Procedure Acquisition List
Get a list of ProcedureAcquisition objects. ProcedureAcquisitions have a 1:1 mapping with Observations.
GET /api/v3/acquisitions/?format=api&offset=4500
{ "count": 5833, "next": "https://api.catalogue.ceda.ac.uk/api/v3/acquisitions/?format=api&limit=100&offset=4600", "previous": "https://api.catalogue.ceda.ac.uk/api/v3/acquisitions/?format=api&limit=100&offset=4400", "results": [ { "ob_id": 30515, "uuid": "36541e8eaa5e4cffa6620eca333485a8", "short_code": "acq", "title": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: surface snow surface brightness temperature taken at Summit Station Greenland", "abstract": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: surface snow surface brightness temperature taken at Summit Station Greenland", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12323, "platform": { "ob_id": 30506, "uuid": "c58202085ddb493988be0fea4e1b065f", "short_code": "plat", "title": "Summit Station Greenland", "abstract": "The Summit Station in Greenland is located (72° 36’N, 38° 25’W, 3250m), atop the Greenland Ice Sheet making it a unique location for a cloud– atmosphere observatory. The station is about 400 km from the east and west coastlines and more than 1,000 km from the southwest and southeast coasts, from which most of the flow impinging on Summit originates, making it a distinctly continental environment. Additionally, the high altitude leads to extremely cold and dry conditions and a relative compression of the troposphere above the ice sheet." }, "instrument": { "ob_id": 30514, "uuid": "0c930a24be924ece9e4c123c81a85e42", "short_code": "instr", "title": "ICECAPS-ACE: KT15 Infrared Temperature sensor", "abstract": "Heitronics KT15 IR temperature sensor (number 1) is a digital, compact, programmable and universally applicable radiation pyrometer series with comprehensive and flexible functions for industrial temperature monitoring and control. It measures surface temperature remotely from infrared radiation.\r\n\r\nThe KT15.85 IIP model is able to measure between -25 and 200 °C.\r\n\r\nData are measured and outputted at 1Hz.\r\n\r\nIt features:\r\n- Extreme high stability due to Chopped Radiation Method\r\n- Very high resolution 0.03 °C\r\n- Fast response times from 5 ms on low temperatures\r\n- Very high linearization accuracy (0.02K)\r\n- Fields-of-view from 0.7 mm at low temperatures allow high optical resolutions\r\n- Permanent self-monitoring routines ensure a reliable operation\r\n- Integrated calibration routine allows for fast and reliable control of the device.\r\n\r\nThese data were collected as part of the joint Natural Environmental Research Council (NERC) and US National Science Foundation (NSF) -funded Integrated Characterisation of Energy, Clouds, Atmospheric state, and Precipitation at Summit - Aerosol Cloud Experiment (ICECAPS-ACE) project." }, "relatedTo": { "ob_id": 30515, "uuid": "36541e8eaa5e4cffa6620eca333485a8", "short_code": "acq", "title": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: surface snow surface brightness temperature taken at Summit Station Greenland", "abstract": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: surface snow surface brightness temperature taken at Summit Station Greenland" } } ] }, { "ob_id": 30518, "uuid": "b93898380bd74bb5831980b4e231894c", "short_code": "acq", "title": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: surface moisture profile taken at Summit Station Greenland", "abstract": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: surface moisture profile taken at Summit Station Greenland", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12324, "platform": { "ob_id": 30506, "uuid": "c58202085ddb493988be0fea4e1b065f", "short_code": "plat", "title": "Summit Station Greenland", "abstract": "The Summit Station in Greenland is located (72° 36’N, 38° 25’W, 3250m), atop the Greenland Ice Sheet making it a unique location for a cloud– atmosphere observatory. The station is about 400 km from the east and west coastlines and more than 1,000 km from the southwest and southeast coasts, from which most of the flow impinging on Summit originates, making it a distinctly continental environment. Additionally, the high altitude leads to extremely cold and dry conditions and a relative compression of the troposphere above the ice sheet." }, "instrument": { "ob_id": 30517, "uuid": "ad664313257843ef820f5f9a6671eac1", "short_code": "instr", "title": "ICECAPS-ACE: temperature and humidity sensors", "abstract": "Four Vaisala HMP155 T/RH sensors with heated probe. Each sensor is mounted on the Met tower at Summit station inside an aspirated shield. \r\n\r\nTower location: -38.470361E, 72.572962N\r\nTower top elevation: 3267 masl\r\nHMP1 elevation: Tower top - 12.3 m \r\nHMP2 elevation: Tower top - 9.8 m \r\nHMP3 elevation: Tower top - 4.5 m \r\nHMP4 elevation: Tower top - 1.0 m\r\n\r\nThese data were collected as part of the joint Natural Environmental Research Council (NERC) and US National Science Foundation (NSF) -funded Integrated Characterisation of Energy, Clouds, Atmospheric state, and Precipitation at Summit - Aerosol Cloud Experiment (ICECAPS-ACE) project." }, "relatedTo": { "ob_id": 30518, "uuid": "b93898380bd74bb5831980b4e231894c", "short_code": "acq", "title": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: surface moisture profile taken at Summit Station Greenland", "abstract": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: surface moisture profile taken at Summit Station Greenland" } } ] }, { "ob_id": 30522, "uuid": "d0c0e525a3a0415d92007e50d8191154", "short_code": "acq", "title": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: snow height change taken at Summit Station Greenland", "abstract": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: snow height change taken at Summit Station Greenland", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12325, "platform": { "ob_id": 30506, "uuid": "c58202085ddb493988be0fea4e1b065f", "short_code": "plat", "title": "Summit Station Greenland", "abstract": "The Summit Station in Greenland is located (72° 36’N, 38° 25’W, 3250m), atop the Greenland Ice Sheet making it a unique location for a cloud– atmosphere observatory. The station is about 400 km from the east and west coastlines and more than 1,000 km from the southwest and southeast coasts, from which most of the flow impinging on Summit originates, making it a distinctly continental environment. Additionally, the high altitude leads to extremely cold and dry conditions and a relative compression of the troposphere above the ice sheet." }, "instrument": { "ob_id": 30521, "uuid": "cc11cd5f3d86477cb19542e8724fd443", "short_code": "instr", "title": "ICECAPS-ACE: Sonic distance sensor", "abstract": "The SR50AH Heated Sonic Distance Sensor provides a non-contact method for determining snow depth. It determines depth by emitting an ultrasonic pulse and then measuring the elapsed time between the emission and return of the pulse. An air temperature measurement is required to correct for variations of the speed of sound in air. The SR50AH includes an integrated heater that prevents ice and rime from coating the transducer.\r\n\r\nThese data were collected as part of the joint Natural Environmental Research Council (NERC) and US National Science Foundation (NSF) -funded Integrated Characterisation of Energy, Clouds, Atmospheric state, and Precipitation at Summit - Aerosol Cloud Experiment (ICECAPS-ACE) project." }, "relatedTo": { "ob_id": 30522, "uuid": "d0c0e525a3a0415d92007e50d8191154", "short_code": "acq", "title": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: snow height change taken at Summit Station Greenland", "abstract": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: snow height change taken at Summit Station Greenland" } } ] }, { "ob_id": 30528, "uuid": "c96183e0c2404079bea95db62d9e00b5", "short_code": "acq", "title": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: surface wind profiles taken at Summit Station Greenland", "abstract": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: surface wind profiles taken at Summit Station Greenland", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12326, "platform": { "ob_id": 30506, "uuid": "c58202085ddb493988be0fea4e1b065f", "short_code": "plat", "title": "Summit Station Greenland", "abstract": "The Summit Station in Greenland is located (72° 36’N, 38° 25’W, 3250m), atop the Greenland Ice Sheet making it a unique location for a cloud– atmosphere observatory. The station is about 400 km from the east and west coastlines and more than 1,000 km from the southwest and southeast coasts, from which most of the flow impinging on Summit originates, making it a distinctly continental environment. Additionally, the high altitude leads to extremely cold and dry conditions and a relative compression of the troposphere above the ice sheet." }, "instrument": { "ob_id": 30527, "uuid": "564902c867344874990aa33a807d3ab1", "short_code": "instr", "title": "ICECAPS-ACE: heated anemometer", "abstract": "Surface wind profiles measured using the following anemometers:\r\n\r\nLufft VentusX, heated 2D sonic anemometer. \r\nMetek uSonic-3 Scientific, heated 3D sonic anemometer. \r\n\r\nEach sensor is mounted on the Met tower at Summit station.\r\n\r\nThese data were collected as part of the joint Natural Environmental Research Council (NERC) and US National Science Foundation (NSF) -funded Integrated Characterisation of Energy, Clouds, Atmospheric state, and Precipitation at Summit - Aerosol Cloud Experiment (ICECAPS-ACE) project." }, "relatedTo": { "ob_id": 30528, "uuid": "c96183e0c2404079bea95db62d9e00b5", "short_code": "acq", "title": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: surface wind profiles taken at Summit Station Greenland", "abstract": "ICECAPS-ACE: Summit Aerosol Cloud Experiment: surface wind profiles taken at Summit Station Greenland" } } ] }, { "ob_id": 30538, "uuid": "35b3c376dd124115aac4aa2495fb928d", "short_code": "acq", "title": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Llanos de Moxos, Bolivia 2019", "abstract": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Llanos de Moxos, Bolivia 2019", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12327, "platform": { "ob_id": 30539, "uuid": "1731a99804b84284910aa3ddf9522360", "short_code": "plat", "title": "Llanos de Moxos wetland", "abstract": "Llanos de Moxos wetland is located near Trinidad, Bolivia." }, "instrument": { "ob_id": 13716, "uuid": "001ac5064d58419980facd285a6085e2", "short_code": "instr", "title": "RHUL-continuous-flow gas chromatography/isotope-ratio mass spectrometry (CF-GC/IRMS) system", "abstract": "The instrument is a mass spectrometer, modified for use to determine isotopic ratios of carbon12/carbon13 in either carbon dioxide (CO2) or methane (CH4). \r\n\r\nFor methane, the CO2 and carbon monoxide (CO) is removed from the sample through liquid nitrogen cryotraps and heaters. The remaining CH4 is converted to CO2 through heating and carried through to a mass spectrometer for analysis of masses 44,45 and 46, so the only remaining CO2 is from the converted CH4. \r\n\r\nSampling frequency is discrete with a precision of ~0.05 per mil. See documents for more detailed information about the instrument. " }, "relatedTo": { "ob_id": 30538, "uuid": "35b3c376dd124115aac4aa2495fb928d", "short_code": "acq", "title": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Llanos de Moxos, Bolivia 2019", "abstract": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Llanos de Moxos, Bolivia 2019" } } ] }, { "ob_id": 30542, "uuid": "5ad3b6b5b56f4531985c6bc3c7f4bd59", "short_code": "acq", "title": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Chacaltya Observatory Station, Bolivia 2014 to 2019", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [ 13716 ], "instrumentplatformpair_set": [] }, { "ob_id": 30546, "uuid": "7ef6978f0617472c80bd35f168af6296", "short_code": "acq", "title": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Cape Point Observatory Station, South Africa 2011 to 2016", "abstract": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Cape Point Observatory Station, South Africa 2011 to 2016", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [ 13716 ], "instrumentplatformpair_set": [ { "ob_id": 12328, "platform": { "ob_id": 30547, "uuid": "5a024bc936834528bf30efec8364c379", "short_code": "plat", "title": "Cape Point", "abstract": "Cape Point is a promontory at the southeast corner of the Cape Peninsula, which is a mountainous and scenic landform that runs north-south for about thirty kilometres at the extreme southwestern tip of the African continent in the Republic of South Africa. Table Mountain and the city of Cape Town are close to the northern extremity of the same peninsula. The cape is located at 34°21′26″S 18°29′51″ECoordinates: 34°21′26″S 18°29′51″E, about 2.3 kilometres (1.4 mi) east and a little north of the Cape of Good Hope on the southwest corner" }, "instrument": { "ob_id": 13716, "uuid": "001ac5064d58419980facd285a6085e2", "short_code": "instr", "title": "RHUL-continuous-flow gas chromatography/isotope-ratio mass spectrometry (CF-GC/IRMS) system", "abstract": "The instrument is a mass spectrometer, modified for use to determine isotopic ratios of carbon12/carbon13 in either carbon dioxide (CO2) or methane (CH4). \r\n\r\nFor methane, the CO2 and carbon monoxide (CO) is removed from the sample through liquid nitrogen cryotraps and heaters. The remaining CH4 is converted to CO2 through heating and carried through to a mass spectrometer for analysis of masses 44,45 and 46, so the only remaining CO2 is from the converted CH4. \r\n\r\nSampling frequency is discrete with a precision of ~0.05 per mil. See documents for more detailed information about the instrument. " }, "relatedTo": { "ob_id": 30546, "uuid": "7ef6978f0617472c80bd35f168af6296", "short_code": "acq", "title": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Cape Point Observatory Station, South Africa 2011 to 2016", "abstract": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Cape Point Observatory Station, South Africa 2011 to 2016" } } ] }, { "ob_id": 30550, "uuid": "e238399044e14ab487aa5f2abfc2e048", "short_code": "acq", "title": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Royal Holloway Earth Sciences Monitoring Station, Egham, UK, 2015 to 2020", "abstract": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Royal Holloway Earth Sciences Monitoring Station, Egham, UK, 2015 to 2020", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12329, "platform": { "ob_id": 30551, "uuid": "c10b0555c93d414e95a3714180ef23eb", "short_code": "plat", "title": "Royal Holloway Earth Sciences Monitoring Station", "abstract": "Royal Holloway Earth Sciences Monitoring Station" }, "instrument": { "ob_id": 13716, "uuid": "001ac5064d58419980facd285a6085e2", "short_code": "instr", "title": "RHUL-continuous-flow gas chromatography/isotope-ratio mass spectrometry (CF-GC/IRMS) system", "abstract": "The instrument is a mass spectrometer, modified for use to determine isotopic ratios of carbon12/carbon13 in either carbon dioxide (CO2) or methane (CH4). \r\n\r\nFor methane, the CO2 and carbon monoxide (CO) is removed from the sample through liquid nitrogen cryotraps and heaters. The remaining CH4 is converted to CO2 through heating and carried through to a mass spectrometer for analysis of masses 44,45 and 46, so the only remaining CO2 is from the converted CH4. \r\n\r\nSampling frequency is discrete with a precision of ~0.05 per mil. See documents for more detailed information about the instrument. " }, "relatedTo": { "ob_id": 30550, "uuid": "e238399044e14ab487aa5f2abfc2e048", "short_code": "acq", "title": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Royal Holloway Earth Sciences Monitoring Station, Egham, UK, 2015 to 2020", "abstract": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Royal Holloway Earth Sciences Monitoring Station, Egham, UK, 2015 to 2020" } } ] }, { "ob_id": 30554, "uuid": "dca44568ba2c49ee851aa7c2a849993d", "short_code": "acq", "title": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Hong Kong 2017-2019", "abstract": "Acquisition for: Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Hong Kong 2017-2019", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [ 13716 ], "instrumentplatformpair_set": [] }, { "ob_id": 30557, "uuid": "e3409b6b51fa4cdd916dcb172df2c622", "short_code": "acq", "title": "Acquisition for: Methane production in the Artic: Isotopic d13C methane measurements taken from Alaskan wetland, 2018 - 2019", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [ 13716 ], "instrumentplatformpair_set": [] }, { "ob_id": 30558, "uuid": "1c3aa52da4ef43fa837d684930569089", "short_code": "acq", "title": "__MUST_UPDATE__20200608133202__ ARSF 2014_309 - MA14_14 Flight: data acquisition details", "abstract": "ARSF 2014_309 - MA14_14 Flight data acquisition details.", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 27631, "uuid": "a385d6248689489382c7569cebd0e3bd", "short_code": "mpop", "title": "ARSF flight 2014_309", "abstract": "ARSF flight 2014_309" } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12330, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 30558, "uuid": "1c3aa52da4ef43fa837d684930569089", "short_code": "acq", "title": "__MUST_UPDATE__20200608133202__ ARSF 2014_309 - MA14_14 Flight: data acquisition details", "abstract": "ARSF 2014_309 - MA14_14 Flight data acquisition details." } }, { "ob_id": 12331, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 30558, "uuid": "1c3aa52da4ef43fa837d684930569089", "short_code": "acq", "title": "__MUST_UPDATE__20200608133202__ ARSF 2014_309 - MA14_14 Flight: data acquisition details", "abstract": "ARSF 2014_309 - MA14_14 Flight data acquisition details." } }, { "ob_id": 12332, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 30558, "uuid": "1c3aa52da4ef43fa837d684930569089", "short_code": "acq", "title": "__MUST_UPDATE__20200608133202__ ARSF 2014_309 - MA14_14 Flight: data acquisition details", "abstract": "ARSF 2014_309 - MA14_14 Flight data acquisition details." } } ] }, { "ob_id": 30559, "uuid": "d02d0cecbc3d44e298371b5cd4124413", "short_code": "acq", "title": "__MUST_UPDATE__20200608133204__ ARSF 2014_309 - MA14_14 Flight: data acquisition details", "abstract": "ARSF 2014_309 - MA14_14 Flight data acquisition details.", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 27631, "uuid": "a385d6248689489382c7569cebd0e3bd", "short_code": "mpop", "title": "ARSF flight 2014_309", "abstract": "ARSF flight 2014_309" } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12333, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 30559, "uuid": "d02d0cecbc3d44e298371b5cd4124413", "short_code": "acq", "title": "__MUST_UPDATE__20200608133204__ ARSF 2014_309 - MA14_14 Flight: data acquisition details", "abstract": "ARSF 2014_309 - MA14_14 Flight data acquisition details." } }, { "ob_id": 12334, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 30559, "uuid": "d02d0cecbc3d44e298371b5cd4124413", "short_code": "acq", "title": "__MUST_UPDATE__20200608133204__ ARSF 2014_309 - MA14_14 Flight: data acquisition details", "abstract": "ARSF 2014_309 - MA14_14 Flight data acquisition details." } }, { "ob_id": 12335, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 30559, "uuid": "d02d0cecbc3d44e298371b5cd4124413", "short_code": "acq", "title": "__MUST_UPDATE__20200608133204__ ARSF 2014_309 - MA14_14 Flight: data acquisition details", "abstract": "ARSF 2014_309 - MA14_14 Flight data acquisition details." } } ] }, { "ob_id": 30560, "uuid": "2dd6d4e99595497ab78187b681604d81", "short_code": "acq", "title": "__MUST_UPDATE__20200608133211__ ARSF 2014_309 - MA14_14 Flight: data acquisition details", "abstract": "ARSF 2014_309 - MA14_14 Flight data acquisition details.", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 27631, "uuid": "a385d6248689489382c7569cebd0e3bd", "short_code": "mpop", "title": "ARSF flight 2014_309", "abstract": "ARSF flight 2014_309" } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12336, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 30560, "uuid": "2dd6d4e99595497ab78187b681604d81", "short_code": "acq", "title": "__MUST_UPDATE__20200608133211__ ARSF 2014_309 - MA14_14 Flight: data acquisition details", "abstract": "ARSF 2014_309 - MA14_14 Flight data acquisition details." } }, { "ob_id": 12337, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 30560, "uuid": "2dd6d4e99595497ab78187b681604d81", "short_code": "acq", "title": "__MUST_UPDATE__20200608133211__ ARSF 2014_309 - MA14_14 Flight: data acquisition details", "abstract": "ARSF 2014_309 - MA14_14 Flight data acquisition details." } }, { "ob_id": 12338, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 30560, "uuid": "2dd6d4e99595497ab78187b681604d81", "short_code": "acq", "title": "__MUST_UPDATE__20200608133211__ ARSF 2014_309 - MA14_14 Flight: data acquisition details", "abstract": "ARSF 2014_309 - MA14_14 Flight data acquisition details." } } ] }, { "ob_id": 30614, "uuid": "e9d23ef7634d469a87b25297a88ea3d5", "short_code": "acq", "title": "Acquisition for: Hourly averaged 4-pi filter radiometer measurements at Auchencorth Moss (21/11/2018 - 20/11/2019) near Edinburgh (UK)", "abstract": "Acquisition for: Hourly averaged 4-pi filter radiometer measurements at Auchencorth Moss (21/11/2018 - 20/11/2019) near Edinburgh (UK)", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12339, "platform": { "ob_id": 6687, "uuid": "4fc04d0f05ea4619845f04aed761e540", "short_code": "plat", "title": "Centre for Ecology and Hydrology (CEH) Auchencorth Moss field site", "abstract": "The Auchencorth Moss site, located in an elevated rural environment, 1.5 kilometres north west of the A701 at Leadburn and 18 kilometres south of Edinburgh city centre, Scotland, near Penicuik. It has been operational since 1985 as part of a variety of different monitoring networks, including being one of two two Level III 'supersites' located in the UK of the EMEP (the Co-operative Programme for Monitoring and Evaluation of the Long-range Transmission of Air Pollutants in Europe) monitoring network. Hourly and daily measurements are supplemented by long-term integrated measurements from existing DEFRA-funded monitoring networks across the UK (http://www.nilu.no/projects/ccc/network/index.html) Auchencorth Moss is the northern of these two sites (the other is near Harwell, Oxfordshire), which has been used by the Centre for Ecology & Hydrology for several years as an intensive monitoring site for trace gas and particle concentrations and fluxes. The site is based in an area of upland deep peat, with heather and grass cover, and has an extensive fetch to the south-west. The site is located at 55.792160 N, 3.242900W (OS Grid map reference: NT 322166, 656128) and at an altitude of 260m above mean sea level. The site is mostly funded by DEFRA but with significant CEH support, part-funded by EU ACTRIS Programme. The CEH field team carry out routine monitoring work for DEFRA and other funding agency contracts. Intermittent research activities are carried out by scientists both from CEH and other UK and international organisations. As a result of the large number of parameter measured at the site it is part of a wide range of monitoring networks. For details of these networks visit the DEFRA station details page. Details of individual activities should be found either on relevant databases (including the BADC) or by contacting CEH for further information. The station's UK-AIR ID is UKA00451 and its EU Site ID (EMEP network identifier) is GB0048R." }, "instrument": { "ob_id": 30615, "uuid": "2ab86dc13efb42c192b4b1942f02cd0b", "short_code": "instr", "title": "UK Centre for Ecology & Hydrology j(NO2) 4-pi filter radiometer", "abstract": "Measured broadband j(NO2) photolysis rate constants from down- and upwelling directions at Auchencorth Moss." }, "relatedTo": { "ob_id": 30614, "uuid": "e9d23ef7634d469a87b25297a88ea3d5", "short_code": "acq", "title": "Acquisition for: Hourly averaged 4-pi filter radiometer measurements at Auchencorth Moss (21/11/2018 - 20/11/2019) near Edinburgh (UK)", "abstract": "Acquisition for: Hourly averaged 4-pi filter radiometer measurements at Auchencorth Moss (21/11/2018 - 20/11/2019) near Edinburgh (UK)" } } ] }, { "ob_id": 30619, "uuid": "690cfc87f69441ada645eb00b2fbffde", "short_code": "acq", "title": "Acquisition for: ZWAMPS: Isotopic d13C methane measurements taken from, Zambia 2019", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [ 13716 ], "instrumentplatformpair_set": [] }, { "ob_id": 31557, "uuid": "6100059eaf5a47af89137321b903ba9e", "short_code": "acq", "title": "Acquisition for Met Office Raman Lidar obs for ex hurricane Ophelia", "abstract": "Acquisition for Met Office Raman Lidar obs for ex hurricane Ophelia", "imageDetails": [ 69 ], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12340, "platform": { "ob_id": 12460, "uuid": "d716b34f2dee47128e93691f70b8dff0", "short_code": "plat", "title": "Met Office Weather Station, Camborne, UK", "abstract": "The Met Office operate a weather station (WMO id 03808) near Camborne, Cornwall, located 87m above mean sea level in Cornwall, south-west UK. Since 1978 meteorological observations have been recorded on a 24 hr basis, linking the station to the synoptic network of the Met Office Meteorological Service. The site is located at OS grid reference SW 627406 . More information can be found in the linked documents. Upper air observations from the site have also been made via ceilometer, radiosonde and boundary-layer wind profiler." }, "instrument": { "ob_id": 26255, "uuid": "e9c0a99af62c4506b2af5da7c75c82b2", "short_code": "instr", "title": "Met Office: Raymetrics LR111-D300 Raman lidar", "abstract": "The Met Office operate a network of 10 Raymetrics LR111-D300 Raman lidars as part of their aerosol remote sensing capability. The network consists of nine fixed locations evenly distributed across Britain, and one mobile facility normally located at Watnall near Nottingham (Adam et al. 2017). The first lidar was installed at the Camborne site in 2015, and the network was fully installed by September 2016. The lidars, Raymetrics LR111-300s, are bespoke systems developed and manufactured by Raymetrics to meet the Met Office and London Volcanic Ash Advisory Centre (VAAC) needs. The instruments emit at 355nm and have polar and co-polar depolarisation detection channels at 355nm, and an N2 Raman detection channel at 387nm. The polarization channels of each lidar are calibrated using the + / - 45 degree procedure from Freudenthaler et al. 2009. Alignment is ensured using the telecover test described in Freudenthaler et al. 2018. Co-located with the lidars are Cimel CE318 multiband sun-photometers, which are part of the AERONET network. Each lidar is operated remotely from the Met Office Exeter headquarters. The primary aim of the network is the detection and quantification of volcanic ash aerosols during a volcanic event, and the network is only test fired only for a few hours each week. Outside of these times the lidars may be fired if there is a mineral dust outbreak or other such aerosol event of interest. The lidars will not fire if any precipitation is detected.\r\n\r\nTransmitter: Quantel CFR200 laser at 355nm, with 50mJ/pulse at 20Hz (i.e. 1W) and is \"eye-safe\"\r\nReceiver: 30cm diameter telescope\r\nDetectors for 355nm (parallel and perpendicular polarization) and 387nm (N2 Raman channel)\r\nBeam and receiving telescope's field of view having complete overlap at ~250m.\r\nLidar beam has a near-vertically pointing direction.\r\n\r\nAdam, M., Buxmann, J., Freeman, N., Horseman, A., Slamon, C., Sugier, J., and Bennett, R.: The UK Lidar-Sunphotometer Operational Volcanic Ash Monitoring Network, in: Proceedings of the 28th International Laser Radar Conference, 2017.\r\n\r\nFreudenthaler, V., Esselborne, M., Wiegner, M., Heese, B., Tesche, M., Ansmann, A., Muller, D., Althausen, D., Wirth, M., Fix, A., Ehret, G., Knippertz, P., Toledano, C., Gasteiger, J., Garhammer, M., and Seefeldner, M.: Depolarization ratio profiling at several wavelengths in pure Saharan dust during SAMUM 2006, Tellus B, 61, 165-179, http://dx.doi.org/10.1111/j.1600-0889.2008.00396.x, 2009.\r\n\r\nFreudenthaler, V., Linné, H., Chaikovski, A., Rabus, D., and Groß, S.: EARLINET lidar quality assurance tools, Atmospheric Measurement Techniques Discussions, 2018, 1-35, https://doi.org/10.5194/amt-2017-395, https://www.atmos-meas-tech-discuss.net/amt-2017-395/, 2018." }, "relatedTo": { "ob_id": 31557, "uuid": "6100059eaf5a47af89137321b903ba9e", "short_code": "acq", "title": "Acquisition for Met Office Raman Lidar obs for ex hurricane Ophelia", "abstract": "Acquisition for Met Office Raman Lidar obs for ex hurricane Ophelia" } }, { "ob_id": 12341, "platform": { "ob_id": 1012, "uuid": "358641354ff546c2a761c9094c414373", "short_code": "plat", "title": "Met Office Nottingham Watnall site, UK", "abstract": "The Met Office operate an observation site at Nottingham Watnall (WMO id 03354) hosting a suite of instruments including surface meteorological observations, laser ceilometer and has been used for radiosonde launches. The station is located 117m above mean sea level in Nottinghamshire, east UK. Since 1941 meteorological observations have been recorded on a 24hr basis, linking the station to the synoptic network of the Met Office Meteorological Service. The site is located at OS grid reference SK 503456. More information can be found in the linked documents.\n\nSite WIGOS id: 0-20000-0-03354. See online documentation for link to station details in the Observing Systems Capability Analysis and Review (OSCAR) Tool." }, "instrument": { "ob_id": 26255, "uuid": "e9c0a99af62c4506b2af5da7c75c82b2", "short_code": "instr", "title": "Met Office: Raymetrics LR111-D300 Raman lidar", "abstract": "The Met Office operate a network of 10 Raymetrics LR111-D300 Raman lidars as part of their aerosol remote sensing capability. The network consists of nine fixed locations evenly distributed across Britain, and one mobile facility normally located at Watnall near Nottingham (Adam et al. 2017). The first lidar was installed at the Camborne site in 2015, and the network was fully installed by September 2016. The lidars, Raymetrics LR111-300s, are bespoke systems developed and manufactured by Raymetrics to meet the Met Office and London Volcanic Ash Advisory Centre (VAAC) needs. The instruments emit at 355nm and have polar and co-polar depolarisation detection channels at 355nm, and an N2 Raman detection channel at 387nm. The polarization channels of each lidar are calibrated using the + / - 45 degree procedure from Freudenthaler et al. 2009. Alignment is ensured using the telecover test described in Freudenthaler et al. 2018. Co-located with the lidars are Cimel CE318 multiband sun-photometers, which are part of the AERONET network. Each lidar is operated remotely from the Met Office Exeter headquarters. The primary aim of the network is the detection and quantification of volcanic ash aerosols during a volcanic event, and the network is only test fired only for a few hours each week. Outside of these times the lidars may be fired if there is a mineral dust outbreak or other such aerosol event of interest. The lidars will not fire if any precipitation is detected.\r\n\r\nTransmitter: Quantel CFR200 laser at 355nm, with 50mJ/pulse at 20Hz (i.e. 1W) and is \"eye-safe\"\r\nReceiver: 30cm diameter telescope\r\nDetectors for 355nm (parallel and perpendicular polarization) and 387nm (N2 Raman channel)\r\nBeam and receiving telescope's field of view having complete overlap at ~250m.\r\nLidar beam has a near-vertically pointing direction.\r\n\r\nAdam, M., Buxmann, J., Freeman, N., Horseman, A., Slamon, C., Sugier, J., and Bennett, R.: The UK Lidar-Sunphotometer Operational Volcanic Ash Monitoring Network, in: Proceedings of the 28th International Laser Radar Conference, 2017.\r\n\r\nFreudenthaler, V., Esselborne, M., Wiegner, M., Heese, B., Tesche, M., Ansmann, A., Muller, D., Althausen, D., Wirth, M., Fix, A., Ehret, G., Knippertz, P., Toledano, C., Gasteiger, J., Garhammer, M., and Seefeldner, M.: Depolarization ratio profiling at several wavelengths in pure Saharan dust during SAMUM 2006, Tellus B, 61, 165-179, http://dx.doi.org/10.1111/j.1600-0889.2008.00396.x, 2009.\r\n\r\nFreudenthaler, V., Linné, H., Chaikovski, A., Rabus, D., and Groß, S.: EARLINET lidar quality assurance tools, Atmospheric Measurement Techniques Discussions, 2018, 1-35, https://doi.org/10.5194/amt-2017-395, https://www.atmos-meas-tech-discuss.net/amt-2017-395/, 2018." }, "relatedTo": { "ob_id": 31557, "uuid": "6100059eaf5a47af89137321b903ba9e", "short_code": "acq", "title": "Acquisition for Met Office Raman Lidar obs for ex hurricane Ophelia", "abstract": "Acquisition for Met Office Raman Lidar obs for ex hurricane Ophelia" } }, { "ob_id": 12342, "platform": { "ob_id": 26271, "uuid": "1d9c08e8afc04876bd85671c48fc7658", "short_code": "plat", "title": "Met Office Loftus Meteorological Station", "abstract": "The Met Office Loftus Meteorological Station (WMO ID: 03275), located in North Yorkshire, has been operated since 1996. The site supports surface and upper air meteorological observations, including Raman lidar operations. It is located 158 m above MSL and has been operational since 1996." }, "instrument": { "ob_id": 26255, "uuid": "e9c0a99af62c4506b2af5da7c75c82b2", "short_code": "instr", "title": "Met Office: Raymetrics LR111-D300 Raman lidar", "abstract": "The Met Office operate a network of 10 Raymetrics LR111-D300 Raman lidars as part of their aerosol remote sensing capability. The network consists of nine fixed locations evenly distributed across Britain, and one mobile facility normally located at Watnall near Nottingham (Adam et al. 2017). The first lidar was installed at the Camborne site in 2015, and the network was fully installed by September 2016. The lidars, Raymetrics LR111-300s, are bespoke systems developed and manufactured by Raymetrics to meet the Met Office and London Volcanic Ash Advisory Centre (VAAC) needs. The instruments emit at 355nm and have polar and co-polar depolarisation detection channels at 355nm, and an N2 Raman detection channel at 387nm. The polarization channels of each lidar are calibrated using the + / - 45 degree procedure from Freudenthaler et al. 2009. Alignment is ensured using the telecover test described in Freudenthaler et al. 2018. Co-located with the lidars are Cimel CE318 multiband sun-photometers, which are part of the AERONET network. Each lidar is operated remotely from the Met Office Exeter headquarters. The primary aim of the network is the detection and quantification of volcanic ash aerosols during a volcanic event, and the network is only test fired only for a few hours each week. Outside of these times the lidars may be fired if there is a mineral dust outbreak or other such aerosol event of interest. The lidars will not fire if any precipitation is detected.\r\n\r\nTransmitter: Quantel CFR200 laser at 355nm, with 50mJ/pulse at 20Hz (i.e. 1W) and is \"eye-safe\"\r\nReceiver: 30cm diameter telescope\r\nDetectors for 355nm (parallel and perpendicular polarization) and 387nm (N2 Raman channel)\r\nBeam and receiving telescope's field of view having complete overlap at ~250m.\r\nLidar beam has a near-vertically pointing direction.\r\n\r\nAdam, M., Buxmann, J., Freeman, N., Horseman, A., Slamon, C., Sugier, J., and Bennett, R.: The UK Lidar-Sunphotometer Operational Volcanic Ash Monitoring Network, in: Proceedings of the 28th International Laser Radar Conference, 2017.\r\n\r\nFreudenthaler, V., Esselborne, M., Wiegner, M., Heese, B., Tesche, M., Ansmann, A., Muller, D., Althausen, D., Wirth, M., Fix, A., Ehret, G., Knippertz, P., Toledano, C., Gasteiger, J., Garhammer, M., and Seefeldner, M.: Depolarization ratio profiling at several wavelengths in pure Saharan dust during SAMUM 2006, Tellus B, 61, 165-179, http://dx.doi.org/10.1111/j.1600-0889.2008.00396.x, 2009.\r\n\r\nFreudenthaler, V., Linné, H., Chaikovski, A., Rabus, D., and Groß, S.: EARLINET lidar quality assurance tools, Atmospheric Measurement Techniques Discussions, 2018, 1-35, https://doi.org/10.5194/amt-2017-395, https://www.atmos-meas-tech-discuss.net/amt-2017-395/, 2018." }, "relatedTo": { "ob_id": 31557, "uuid": "6100059eaf5a47af89137321b903ba9e", "short_code": "acq", "title": "Acquisition for Met Office Raman Lidar obs for ex hurricane Ophelia", "abstract": "Acquisition for Met Office Raman Lidar obs for ex hurricane Ophelia" } }, { "ob_id": 12343, "platform": { "ob_id": 26273, "uuid": "01b48516da934109a808906cd0ba14dc", "short_code": "plat", "title": "Met Office Rhyl Meteorological Station", "abstract": "The Met Office Rhyl Meteorological Station (WMO ID: 03313) is an instrument enclosure located near Rhyl, North Wales, and has been operated since 1986. The site supports surface and upper air meteorological observations, including Raman lidar operations. It is located 77 m above MSL." }, "instrument": { "ob_id": 26255, "uuid": "e9c0a99af62c4506b2af5da7c75c82b2", "short_code": "instr", "title": "Met Office: Raymetrics LR111-D300 Raman lidar", "abstract": "The Met Office operate a network of 10 Raymetrics LR111-D300 Raman lidars as part of their aerosol remote sensing capability. The network consists of nine fixed locations evenly distributed across Britain, and one mobile facility normally located at Watnall near Nottingham (Adam et al. 2017). The first lidar was installed at the Camborne site in 2015, and the network was fully installed by September 2016. The lidars, Raymetrics LR111-300s, are bespoke systems developed and manufactured by Raymetrics to meet the Met Office and London Volcanic Ash Advisory Centre (VAAC) needs. The instruments emit at 355nm and have polar and co-polar depolarisation detection channels at 355nm, and an N2 Raman detection channel at 387nm. The polarization channels of each lidar are calibrated using the + / - 45 degree procedure from Freudenthaler et al. 2009. Alignment is ensured using the telecover test described in Freudenthaler et al. 2018. Co-located with the lidars are Cimel CE318 multiband sun-photometers, which are part of the AERONET network. Each lidar is operated remotely from the Met Office Exeter headquarters. The primary aim of the network is the detection and quantification of volcanic ash aerosols during a volcanic event, and the network is only test fired only for a few hours each week. Outside of these times the lidars may be fired if there is a mineral dust outbreak or other such aerosol event of interest. The lidars will not fire if any precipitation is detected.\r\n\r\nTransmitter: Quantel CFR200 laser at 355nm, with 50mJ/pulse at 20Hz (i.e. 1W) and is \"eye-safe\"\r\nReceiver: 30cm diameter telescope\r\nDetectors for 355nm (parallel and perpendicular polarization) and 387nm (N2 Raman channel)\r\nBeam and receiving telescope's field of view having complete overlap at ~250m.\r\nLidar beam has a near-vertically pointing direction.\r\n\r\nAdam, M., Buxmann, J., Freeman, N., Horseman, A., Slamon, C., Sugier, J., and Bennett, R.: The UK Lidar-Sunphotometer Operational Volcanic Ash Monitoring Network, in: Proceedings of the 28th International Laser Radar Conference, 2017.\r\n\r\nFreudenthaler, V., Esselborne, M., Wiegner, M., Heese, B., Tesche, M., Ansmann, A., Muller, D., Althausen, D., Wirth, M., Fix, A., Ehret, G., Knippertz, P., Toledano, C., Gasteiger, J., Garhammer, M., and Seefeldner, M.: Depolarization ratio profiling at several wavelengths in pure Saharan dust during SAMUM 2006, Tellus B, 61, 165-179, http://dx.doi.org/10.1111/j.1600-0889.2008.00396.x, 2009.\r\n\r\nFreudenthaler, V., Linné, H., Chaikovski, A., Rabus, D., and Groß, S.: EARLINET lidar quality assurance tools, Atmospheric Measurement Techniques Discussions, 2018, 1-35, https://doi.org/10.5194/amt-2017-395, https://www.atmos-meas-tech-discuss.net/amt-2017-395/, 2018." }, "relatedTo": { "ob_id": 31557, "uuid": "6100059eaf5a47af89137321b903ba9e", "short_code": "acq", "title": "Acquisition for Met Office Raman Lidar obs for ex hurricane Ophelia", "abstract": "Acquisition for Met Office Raman Lidar obs for ex hurricane Ophelia" } } ] }, { "ob_id": 31568, "uuid": "7d1b3c06078a477e86f9a9c5abaecc61", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [ 20341 ], "instrumentplatformpair_set": [] }, { "ob_id": 31571, "uuid": "af55f6ad12844f218cf29e96362c6c7a", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31578, "uuid": "4262c568e242427dbda3a69ba8cd94ef", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31582, "uuid": "9f46e9e6936b4885b63769c4d9fe8c9d", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31585, "uuid": "211d104f69024940aa731a4ca8629f27", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31588, "uuid": "c2388cd5ba88410f85ba140d29f23fd6", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31591, "uuid": "3a9d2c4a35fe444dbc7c8620f05c8fab", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31595, "uuid": "29f0087b1cff40698667ebb9ab9ca800", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31599, "uuid": "5b6e3031c74b4ee98b163b9dc4358fa5", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31603, "uuid": "48fd587628684cb9bf0b1a6e09de8d4f", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31607, "uuid": "a47a7de973e6462aab1eeeb8274f056d", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31611, "uuid": "b250536882a142049166feaad72fd73b", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31615, "uuid": "30d27b2c23b240d59c6e94a6f6de6eb4", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31619, "uuid": "2a75e379a3a5425ca6cd19bebf189253", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31623, "uuid": "70e85a2195fe44338c63593827c5b8f7", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31627, "uuid": "51cf6242269a41b283388d80250f5527", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31631, "uuid": "ca57b1c5ad4d44fc872a152870c8355c", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31635, "uuid": "35140438df434e52a04771a64c85e62a", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31639, "uuid": "8373da9c8a9d40eba2d9ce0b68f57319", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12344, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 31639, "uuid": "8373da9c8a9d40eba2d9ce0b68f57319", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31643, "uuid": "a32997f5920a4b2b9f7ed78e6f05a88f", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12345, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 31643, "uuid": "a32997f5920a4b2b9f7ed78e6f05a88f", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12346, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 31643, "uuid": "a32997f5920a4b2b9f7ed78e6f05a88f", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12347, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 31643, "uuid": "a32997f5920a4b2b9f7ed78e6f05a88f", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12348, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24845, "uuid": "4f82e9e3c71140d499e7dbbe5d50da00", "short_code": "instr", "title": "NERC-ARF Specim AISA Owl", "abstract": "The Specim AISAOwl is a hyperspectral imager on board the NERC-ARF aircraft measuring the Long Wave InfraRed (LWIR) wavelengths, specifically 7.5–12.5 um with 102 bands. It is a passive pushbroom sensor measuring primarily emitted radiation, which can be used to derive temperature and emissivity." }, "relatedTo": { "ob_id": 31643, "uuid": "a32997f5920a4b2b9f7ed78e6f05a88f", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31653, "uuid": "6b8d7b7a813b4fa4bd3a323160e1e86f", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12349, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 31653, "uuid": "6b8d7b7a813b4fa4bd3a323160e1e86f", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12350, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 31653, "uuid": "6b8d7b7a813b4fa4bd3a323160e1e86f", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12351, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 31653, "uuid": "6b8d7b7a813b4fa4bd3a323160e1e86f", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12352, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24845, "uuid": "4f82e9e3c71140d499e7dbbe5d50da00", "short_code": "instr", "title": "NERC-ARF Specim AISA Owl", "abstract": "The Specim AISAOwl is a hyperspectral imager on board the NERC-ARF aircraft measuring the Long Wave InfraRed (LWIR) wavelengths, specifically 7.5–12.5 um with 102 bands. It is a passive pushbroom sensor measuring primarily emitted radiation, which can be used to derive temperature and emissivity." }, "relatedTo": { "ob_id": 31653, "uuid": "6b8d7b7a813b4fa4bd3a323160e1e86f", "short_code": "acq", "title": "Acquisition for: ARSF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31676, "uuid": "748914fe1674464eb3a48b742bc35f26", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_293 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31679, "uuid": "1ce7f49d1be14ee898c9d446c2515ae6", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_293 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31682, "uuid": "ae9d873214994716b099a776fb9bb870", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_293 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [] }, { "ob_id": 31685, "uuid": "7cc6e4af022045a8ab5767c9fd0b8c18", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_293 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 31686, "uuid": "3977d716314349cb8f2aaf4114c7de82", "short_code": "mpop", "title": "ARSF flight 2014_293", "abstract": "Flight details for NERC-ARSF aircraft flight number 2014_293. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12353, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 31685, "uuid": "7cc6e4af022045a8ab5767c9fd0b8c18", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_293 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12354, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 31685, "uuid": "7cc6e4af022045a8ab5767c9fd0b8c18", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_293 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12355, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 31685, "uuid": "7cc6e4af022045a8ab5767c9fd0b8c18", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_293 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31689, "uuid": "e59eae62ecbb4f83a4254dfd84c51c12", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_291 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 31690, "uuid": "13c546da1b6a4021ba20a8c7dffd233a", "short_code": "mpop", "title": "ARSF flight ARSF2014_291", "abstract": "Flight details for NERC-ARSF aircraft flight number ARSF2014_291. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12356, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 31689, "uuid": "e59eae62ecbb4f83a4254dfd84c51c12", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_291 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12357, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 31689, "uuid": "e59eae62ecbb4f83a4254dfd84c51c12", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_291 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12358, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 31689, "uuid": "e59eae62ecbb4f83a4254dfd84c51c12", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_291 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31693, "uuid": "bc09a3ffb11e4284a074321d78e6a037", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 31694, "uuid": "7664e71dc2f445d5975a3d5521c436f8", "short_code": "mpop", "title": "ARSF flight ARSF2014_290", "abstract": "Flight details for NERC-ARSF aircraft flight number ARSF2014_290. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12359, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 31693, "uuid": "bc09a3ffb11e4284a074321d78e6a037", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12360, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 31693, "uuid": "bc09a3ffb11e4284a074321d78e6a037", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12361, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 31693, "uuid": "bc09a3ffb11e4284a074321d78e6a037", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_290 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31697, "uuid": "b75d3b7dc5304f49a03c9ff2ac66271b", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_288 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 31698, "uuid": "aa2adc204d21489280a345544e253fda", "short_code": "mpop", "title": "ARSF flight ARSF2014_288", "abstract": "Flight details for NERC-ARSF aircraft flight number ARSF2014_288. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12362, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 31697, "uuid": "b75d3b7dc5304f49a03c9ff2ac66271b", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_288 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12363, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 31697, "uuid": "b75d3b7dc5304f49a03c9ff2ac66271b", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_288 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12364, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 31697, "uuid": "b75d3b7dc5304f49a03c9ff2ac66271b", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_288 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31701, "uuid": "95b12a6fbeec40ed80c7b4cff467b542", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_289 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 31702, "uuid": "913fcd87955d4908a2335c7d42ec5f27", "short_code": "mpop", "title": "ARSF flight ARSF2014_289", "abstract": "Flight details for NERC-ARSF aircraft flight number ARSF2014_289. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12365, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 31701, "uuid": "95b12a6fbeec40ed80c7b4cff467b542", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_289 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12366, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 31701, "uuid": "95b12a6fbeec40ed80c7b4cff467b542", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_289 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12367, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 31701, "uuid": "95b12a6fbeec40ed80c7b4cff467b542", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_289 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31705, "uuid": "d560a6eb4923426bb1be6665187247b9", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_294 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 31706, "uuid": "df4af2432dff4411b56600e2bc32031b", "short_code": "mpop", "title": "ARSF flight ARSF2014_294", "abstract": "Flight details for NERC-ARSF aircraft flight number ARSF2014_294. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12368, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 31705, "uuid": "d560a6eb4923426bb1be6665187247b9", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_294 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12369, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 31705, "uuid": "d560a6eb4923426bb1be6665187247b9", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_294 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12370, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 31705, "uuid": "d560a6eb4923426bb1be6665187247b9", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_294 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31709, "uuid": "2c132914f8f54657969acd129edbd983", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_295 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 31710, "uuid": "4dd41cd851834953ab3b63ec05d79567", "short_code": "mpop", "title": "ARSF flight ARSF2014_295", "abstract": "Flight details for NERC-ARSF aircraft flight number ARSF2014_295. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12371, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 31709, "uuid": "2c132914f8f54657969acd129edbd983", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_295 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12372, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 31709, "uuid": "2c132914f8f54657969acd129edbd983", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_295 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12373, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 31709, "uuid": "2c132914f8f54657969acd129edbd983", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_295 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31713, "uuid": "0b00e5e79f024f669ff968d97a50a27e", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_297 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 31714, "uuid": "388d35496ea64d8bb71b1751ea6ade5f", "short_code": "mpop", "title": "ARSF flight ARSF2014_297", "abstract": "Flight details for NERC-ARSF aircraft flight number ARSF2014_297. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12374, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 31713, "uuid": "0b00e5e79f024f669ff968d97a50a27e", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_297 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12375, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 31713, "uuid": "0b00e5e79f024f669ff968d97a50a27e", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_297 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12376, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 31713, "uuid": "0b00e5e79f024f669ff968d97a50a27e", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_297 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31717, "uuid": "bbde2bba402a48bf86a6fe7808616818", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_298 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 31718, "uuid": "5283b87a332947d5a13aa7164fb7fa01", "short_code": "mpop", "title": "ARSF flight ARSF2014_298", "abstract": "Flight details for NERC-ARSF aircraft flight number ARSF2014_298. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12377, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 31717, "uuid": "bbde2bba402a48bf86a6fe7808616818", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_298 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12378, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 31717, "uuid": "bbde2bba402a48bf86a6fe7808616818", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_298 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12379, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 31717, "uuid": "bbde2bba402a48bf86a6fe7808616818", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_298 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31721, "uuid": "8ee9ac6e59574212b8e932b97af0d225", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_302a - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 31722, "uuid": "4f8d72f0b9af4424bf8e73261c21a356", "short_code": "mpop", "title": "ARSF flight ARSF2014_302a", "abstract": "Flight details for NERC-ARSF aircraft flight number ARSF2014_302a. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12380, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 31721, "uuid": "8ee9ac6e59574212b8e932b97af0d225", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_302a - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31725, "uuid": "c61088a538a6461293bf606a57ea8f9e", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_303 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 31726, "uuid": "9a87286ca3d54b4ab17925f8c80d8e9d", "short_code": "mpop", "title": "ARSF flight ARSF2014_303", "abstract": "Flight details for NERC-ARSF aircraft flight number ARSF2014_303. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12381, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 31725, "uuid": "c61088a538a6461293bf606a57ea8f9e", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_303 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12382, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 31725, "uuid": "c61088a538a6461293bf606a57ea8f9e", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_303 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12383, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24846, "uuid": "d5f3a581307b406cae4ff20bc0af1f85", "short_code": "instr", "title": "NERC-ARF Leica ALS50-II LiDAR", "abstract": "The Leica ALS50-II LiDAR is a Light Detection and Ranging instrument flown on the NERC-ARF aircraft capable of producing both discrete point clouds and full-waveform returns. With a laser of wavelength 1064 nm pulsed at 4 ns or 9 ns it is suitable for high accuracy topographic applications. The data can be used to create Digital Elevation Models or represent 3D structures such as tree canopies." }, "relatedTo": { "ob_id": 31725, "uuid": "c61088a538a6461293bf606a57ea8f9e", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_303 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12384, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 24845, "uuid": "4f82e9e3c71140d499e7dbbe5d50da00", "short_code": "instr", "title": "NERC-ARF Specim AISA Owl", "abstract": "The Specim AISAOwl is a hyperspectral imager on board the NERC-ARF aircraft measuring the Long Wave InfraRed (LWIR) wavelengths, specifically 7.5–12.5 um with 102 bands. It is a passive pushbroom sensor measuring primarily emitted radiation, which can be used to derive temperature and emissivity." }, "relatedTo": { "ob_id": 31725, "uuid": "c61088a538a6461293bf606a57ea8f9e", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2014_303 - RG13_06 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 31767, "uuid": "f70c548dcb0148d4b459187280cdded1", "short_code": "acq", "title": "Acquisition for: ICECAPS-ACE: surface turbulent heat flux components", "abstract": "Acquisition for: ICECAPS-ACE: surface turbulent heat flux components", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12385, "platform": { "ob_id": 30506, "uuid": "c58202085ddb493988be0fea4e1b065f", "short_code": "plat", "title": "Summit Station Greenland", "abstract": "The Summit Station in Greenland is located (72° 36’N, 38° 25’W, 3250m), atop the Greenland Ice Sheet making it a unique location for a cloud– atmosphere observatory. The station is about 400 km from the east and west coastlines and more than 1,000 km from the southwest and southeast coasts, from which most of the flow impinging on Summit originates, making it a distinctly continental environment. Additionally, the high altitude leads to extremely cold and dry conditions and a relative compression of the troposphere above the ice sheet." }, "instrument": { "ob_id": 25986, "uuid": "e30e88421dde44ecb46f09736f289e5f", "short_code": "instr", "title": "University of Leeds: Licor Li-7500 gas analyzer", "abstract": "The University of Leeds' LI-COR LI-7500 open path gas analyser operates at infra-red wavelengths measuring the absorption due to carbon dioxide and water vapour concentrations at specific wavelengths along its 0.125m measurement path. Internally-stored calibration data are used to convert these absorption values to a mole concentration for each gas. Measurements are made at 20 Hz frequency." }, "relatedTo": { "ob_id": 31767, "uuid": "f70c548dcb0148d4b459187280cdded1", "short_code": "acq", "title": "Acquisition for: ICECAPS-ACE: surface turbulent heat flux components", "abstract": "Acquisition for: ICECAPS-ACE: surface turbulent heat flux components" } } ] }, { "ob_id": 31788, "uuid": "e0120de39d534374bfa65a6df64126a3", "short_code": "acq", "title": "Iceland Greenland Seas Project (IGP): surface layer meteorological measurements on board the NATO Research Vessel Alliance", "abstract": "Iceland Greenland Seas Project (IGP): surface layer meteorological measurements on board the NATO Research Vessel Alliance", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12386, "platform": { "ob_id": 26503, "uuid": "e494bef9ef884794a65a341e58205eb2", "short_code": "plat", "title": "Alliance Ship", "abstract": "Alliance is a research ship. The 93 meters, 3,180 t NATO ship NRV ALLIANCE was designed in the mid 80’s as a quiet acoustic research platform. It is capable of operating in all oceans strategically important to NATO nations. ALLIANCE enables scientists and engineers from the Centre and partner nations to conduct a wide range of experiments. The ship is equipped with modern scientific instruments, a sophisticated navigation system, and its deck comprises of a vast array of winches (some fitted and some removable), heavy cranes, a lateral frame and a stern U-frame (including a large 4 drum main tow winch for large arrays). This variety of deck equipment allows a large variety of launch and recovery of scientific and engineering sensors, oceanographic instruments, autonomous vehicles and tethered devices." }, "instrument": { "ob_id": 29986, "uuid": "8d7472c544e846c988cb49b3d2358eb9", "short_code": "instr", "title": "University of Bergen: Windcube lidar wind profiler", "abstract": "This is a lidar wind profiler built by leosphere and it belongs to and was operated by University of Bergen" }, "relatedTo": { "ob_id": 31788, "uuid": "e0120de39d534374bfa65a6df64126a3", "short_code": "acq", "title": "Iceland Greenland Seas Project (IGP): surface layer meteorological measurements on board the NATO Research Vessel Alliance", "abstract": "Iceland Greenland Seas Project (IGP): surface layer meteorological measurements on board the NATO Research Vessel Alliance" } }, { "ob_id": 12387, "platform": { "ob_id": 26503, "uuid": "e494bef9ef884794a65a341e58205eb2", "short_code": "plat", "title": "Alliance Ship", "abstract": "Alliance is a research ship. The 93 meters, 3,180 t NATO ship NRV ALLIANCE was designed in the mid 80’s as a quiet acoustic research platform. It is capable of operating in all oceans strategically important to NATO nations. ALLIANCE enables scientists and engineers from the Centre and partner nations to conduct a wide range of experiments. The ship is equipped with modern scientific instruments, a sophisticated navigation system, and its deck comprises of a vast array of winches (some fitted and some removable), heavy cranes, a lateral frame and a stern U-frame (including a large 4 drum main tow winch for large arrays). This variety of deck equipment allows a large variety of launch and recovery of scientific and engineering sensors, oceanographic instruments, autonomous vehicles and tethered devices." }, "instrument": { "ob_id": 26653, "uuid": "f93fa7f9725b406b899db743e9fb402a", "short_code": "instr", "title": "NCAS Scanning Radiometer- HATPRO", "abstract": "NCAS Humidity And Temperature PROfiler (HATPRO) Scanning Microwave Radiometer unit 1, by Radiometer Physics GmbH. is used to derive vertical profiles of atmospheric temperature and humidity. The infrared radiometer extension allows to cloud base height and ice cloud detection.The radiometer offers high-resolution temperature profiling of the boundary layer and low-humidity applications. The radiometer provides accurate total amounts of atmospheric water vapor and cloud liquid content measurements." }, "relatedTo": { "ob_id": 31788, "uuid": "e0120de39d534374bfa65a6df64126a3", "short_code": "acq", "title": "Iceland Greenland Seas Project (IGP): surface layer meteorological measurements on board the NATO Research Vessel Alliance", "abstract": "Iceland Greenland Seas Project (IGP): surface layer meteorological measurements on board the NATO Research Vessel Alliance" } }, { "ob_id": 12388, "platform": { "ob_id": 26503, "uuid": "e494bef9ef884794a65a341e58205eb2", "short_code": "plat", "title": "Alliance Ship", "abstract": "Alliance is a research ship. The 93 meters, 3,180 t NATO ship NRV ALLIANCE was designed in the mid 80’s as a quiet acoustic research platform. It is capable of operating in all oceans strategically important to NATO nations. ALLIANCE enables scientists and engineers from the Centre and partner nations to conduct a wide range of experiments. The ship is equipped with modern scientific instruments, a sophisticated navigation system, and its deck comprises of a vast array of winches (some fitted and some removable), heavy cranes, a lateral frame and a stern U-frame (including a large 4 drum main tow winch for large arrays). This variety of deck equipment allows a large variety of launch and recovery of scientific and engineering sensors, oceanographic instruments, autonomous vehicles and tethered devices." }, "instrument": { "ob_id": 31786, "uuid": "775e776a78994571b448c29d0647e206", "short_code": "instr", "title": "WeatherPak", "abstract": "The WeatherPak monitoring system supplied by Coastal Environmental Systems is a shipboard weather station designed for harsh environments. Using built in GPS and a compass it is able to calculate true winds (accuracy: +/- 0.3 m/s, resolution: 0.1 m/s) and winds relative to ship motion. It includes meteorological sensors for pressure (+/- 0.2 hPa @ 25°C, 1 hPa), temperature (resolution: 0.2°C), relative humidity (resolution: 1%), pitch, heave and roll. Data is transmitted via ship NMEA system. Data can be recorded up to 1 second time resolution." }, "relatedTo": { "ob_id": 31788, "uuid": "e0120de39d534374bfa65a6df64126a3", "short_code": "acq", "title": "Iceland Greenland Seas Project (IGP): surface layer meteorological measurements on board the NATO Research Vessel Alliance", "abstract": "Iceland Greenland Seas Project (IGP): surface layer meteorological measurements on board the NATO Research Vessel Alliance" } }, { "ob_id": 12389, "platform": { "ob_id": 26503, "uuid": "e494bef9ef884794a65a341e58205eb2", "short_code": "plat", "title": "Alliance Ship", "abstract": "Alliance is a research ship. The 93 meters, 3,180 t NATO ship NRV ALLIANCE was designed in the mid 80’s as a quiet acoustic research platform. It is capable of operating in all oceans strategically important to NATO nations. ALLIANCE enables scientists and engineers from the Centre and partner nations to conduct a wide range of experiments. The ship is equipped with modern scientific instruments, a sophisticated navigation system, and its deck comprises of a vast array of winches (some fitted and some removable), heavy cranes, a lateral frame and a stern U-frame (including a large 4 drum main tow winch for large arrays). This variety of deck equipment allows a large variety of launch and recovery of scientific and engineering sensors, oceanographic instruments, autonomous vehicles and tethered devices." }, "instrument": { "ob_id": 31787, "uuid": "e0fdc257fd4942b7856db9f061aadc6a", "short_code": "instr", "title": "SBE38 sea water temperature sensor", "abstract": "The Sea-Bird Scientific digital ocean thermometer features an ultra-stable platinum thermistor and state-of-the-art calibration. As on the NATO Research Vessel Alliance, the SBE 38 can be integrated as a remote sensor with an SBE 45 Micro-Thermosalinograph to provide accurate sea surface temperature, conductivity and salinity measurements. Initial accuracy +/- 0.001 °C, resolution 0.00025 °C." }, "relatedTo": { "ob_id": 31788, "uuid": "e0120de39d534374bfa65a6df64126a3", "short_code": "acq", "title": "Iceland Greenland Seas Project (IGP): surface layer meteorological measurements on board the NATO Research Vessel Alliance", "abstract": "Iceland Greenland Seas Project (IGP): surface layer meteorological measurements on board the NATO Research Vessel Alliance" } } ] }, { "ob_id": 31851, "uuid": "d445bcf8ebb349bea30631656e6717bc", "short_code": "acq", "title": "Acquisition Process for: Drium-A-Starraig Rainfall Data from the Met Office Nimrod System", "abstract": "This acquisition is comprised of the following: INSTRUMENTS: Met Office C-band radar, NIMROD system; PLATFORMS: Drium-A-Starraig Radar Station, UK;", "imageDetails": [ 69 ], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12390, "platform": { "ob_id": 31852, "uuid": "62d820efce93426dbd499e64b11ac486", "short_code": "plat", "title": "Drium a'Starraig", "abstract": "Drium-A-Starraig station is a Met Office operated site where a C-band weather radar was deployed by the Met Office. It is located near Stornaway, Isle\r\nof Lewis." }, "instrument": { "ob_id": 1003, "uuid": "fe89d9092055426eb719290ce4063b88", "short_code": "instr", "title": "Met Office C-band radar", "abstract": "UK C Band radar run by the Met Office and the Environment Agency." }, "relatedTo": { "ob_id": 31851, "uuid": "d445bcf8ebb349bea30631656e6717bc", "short_code": "acq", "title": "Acquisition Process for: Drium-A-Starraig Rainfall Data from the Met Office Nimrod System", "abstract": "This acquisition is comprised of the following: INSTRUMENTS: Met Office C-band radar, NIMROD system; PLATFORMS: Drium-A-Starraig Radar Station, UK;" } }, { "ob_id": 12391, "platform": { "ob_id": 31852, "uuid": "62d820efce93426dbd499e64b11ac486", "short_code": "plat", "title": "Drium a'Starraig", "abstract": "Drium-A-Starraig station is a Met Office operated site where a C-band weather radar was deployed by the Met Office. It is located near Stornaway, Isle\r\nof Lewis." }, "instrument": { "ob_id": 4778, "uuid": "5ea91b27324343c38de54cc5aeb98689", "short_code": "instr", "title": "NIMROD system", "abstract": "NIMROD is a very short range forecasting system which integrates nowcasting techniques with Numerical Weather Prediction (NWP) model products to provide forecasts over the UK and surrounding waters up to six hours ahead. NIMROD produces analyses and forecasts of precipitation, cloud and visibility." }, "relatedTo": { "ob_id": 31851, "uuid": "d445bcf8ebb349bea30631656e6717bc", "short_code": "acq", "title": "Acquisition Process for: Drium-A-Starraig Rainfall Data from the Met Office Nimrod System", "abstract": "This acquisition is comprised of the following: INSTRUMENTS: Met Office C-band radar, NIMROD system; PLATFORMS: Drium-A-Starraig Radar Station, UK;" } } ] }, { "ob_id": 31867, "uuid": "97840d9e49794b6aad67ac7aebd76272", "short_code": "acq", "title": "INCOMPASS: IMD Doppler radar convective cell statistics", "abstract": "INCOMPASS: IMD Doppler radar convective cell statistics", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12392, "platform": { "ob_id": 31860, "uuid": "c07216e49c444f56bfbbdadb26de26eb", "short_code": "plat", "title": "Agartala Airport", "abstract": "Agartala Airport" }, "instrument": { "ob_id": 14231, "uuid": "490b4a087f734478a243eb9fc5b31a9e", "short_code": "instr", "title": "Doppler radars", "abstract": "A Doppler radar is a specialized radar that uses the Doppler effect to produce velocity data about objects at a distance. It does this by bouncing a microwave signal off a desired target and analyzing how the object's motion has altered the frequency of the returned signal. This variation gives direct and highly accurate measurements of the radial component of a target's velocity relative to the radar. " }, "relatedTo": { "ob_id": 31867, "uuid": "97840d9e49794b6aad67ac7aebd76272", "short_code": "acq", "title": "INCOMPASS: IMD Doppler radar convective cell statistics", "abstract": "INCOMPASS: IMD Doppler radar convective cell statistics" } }, { "ob_id": 12393, "platform": { "ob_id": 31861, "uuid": "2c50579b41e24c76b7e995dfd9d69489", "short_code": "plat", "title": "Bhopal, Raja Bhoj Airport", "abstract": "Raja Bhoj Airport" }, "instrument": { "ob_id": 14231, "uuid": "490b4a087f734478a243eb9fc5b31a9e", "short_code": "instr", "title": "Doppler radars", "abstract": "A Doppler radar is a specialized radar that uses the Doppler effect to produce velocity data about objects at a distance. It does this by bouncing a microwave signal off a desired target and analyzing how the object's motion has altered the frequency of the returned signal. This variation gives direct and highly accurate measurements of the radial component of a target's velocity relative to the radar. " }, "relatedTo": { "ob_id": 31867, "uuid": "97840d9e49794b6aad67ac7aebd76272", "short_code": "acq", "title": "INCOMPASS: IMD Doppler radar convective cell statistics", "abstract": "INCOMPASS: IMD Doppler radar convective cell statistics" } }, { "ob_id": 12394, "platform": { "ob_id": 31862, "uuid": "6ebee92684d04907b4566d9d6373c21a", "short_code": "plat", "title": "Chennai", "abstract": "Chennai international airport." }, "instrument": { "ob_id": 14231, "uuid": "490b4a087f734478a243eb9fc5b31a9e", "short_code": "instr", "title": "Doppler radars", "abstract": "A Doppler radar is a specialized radar that uses the Doppler effect to produce velocity data about objects at a distance. It does this by bouncing a microwave signal off a desired target and analyzing how the object's motion has altered the frequency of the returned signal. This variation gives direct and highly accurate measurements of the radial component of a target's velocity relative to the radar. " }, "relatedTo": { "ob_id": 31867, "uuid": "97840d9e49794b6aad67ac7aebd76272", "short_code": "acq", "title": "INCOMPASS: IMD Doppler radar convective cell statistics", "abstract": "INCOMPASS: IMD Doppler radar convective cell statistics" } }, { "ob_id": 12395, "platform": { "ob_id": 31863, "uuid": "5b4c9532af1741b7a36843a39f603099", "short_code": "plat", "title": "Kolkata", "abstract": "Kolkata, Netaji Subhas Chandra Bose International Airport." }, "instrument": { "ob_id": 14231, "uuid": "490b4a087f734478a243eb9fc5b31a9e", "short_code": "instr", "title": "Doppler radars", "abstract": "A Doppler radar is a specialized radar that uses the Doppler effect to produce velocity data about objects at a distance. It does this by bouncing a microwave signal off a desired target and analyzing how the object's motion has altered the frequency of the returned signal. This variation gives direct and highly accurate measurements of the radial component of a target's velocity relative to the radar. " }, "relatedTo": { "ob_id": 31867, "uuid": "97840d9e49794b6aad67ac7aebd76272", "short_code": "acq", "title": "INCOMPASS: IMD Doppler radar convective cell statistics", "abstract": "INCOMPASS: IMD Doppler radar convective cell statistics" } }, { "ob_id": 12396, "platform": { "ob_id": 31864, "uuid": "81180c8f24d84e5bbffa803c539940d9", "short_code": "plat", "title": "Lucknow", "abstract": "Lucknow, Chaudhary Charan Singh International Airport." }, "instrument": { "ob_id": 14231, "uuid": "490b4a087f734478a243eb9fc5b31a9e", "short_code": "instr", "title": "Doppler radars", "abstract": "A Doppler radar is a specialized radar that uses the Doppler effect to produce velocity data about objects at a distance. It does this by bouncing a microwave signal off a desired target and analyzing how the object's motion has altered the frequency of the returned signal. This variation gives direct and highly accurate measurements of the radial component of a target's velocity relative to the radar. " }, "relatedTo": { "ob_id": 31867, "uuid": "97840d9e49794b6aad67ac7aebd76272", "short_code": "acq", "title": "INCOMPASS: IMD Doppler radar convective cell statistics", "abstract": "INCOMPASS: IMD Doppler radar convective cell statistics" } }, { "ob_id": 12397, "platform": { "ob_id": 31865, "uuid": "3beb176aca764de2ad7026fed13f7045", "short_code": "plat", "title": "Machilipatnam", "abstract": "Machilipatnam" }, "instrument": { "ob_id": 14231, "uuid": "490b4a087f734478a243eb9fc5b31a9e", "short_code": "instr", "title": "Doppler radars", "abstract": "A Doppler radar is a specialized radar that uses the Doppler effect to produce velocity data about objects at a distance. It does this by bouncing a microwave signal off a desired target and analyzing how the object's motion has altered the frequency of the returned signal. This variation gives direct and highly accurate measurements of the radial component of a target's velocity relative to the radar. " }, "relatedTo": { "ob_id": 31867, "uuid": "97840d9e49794b6aad67ac7aebd76272", "short_code": "acq", "title": "INCOMPASS: IMD Doppler radar convective cell statistics", "abstract": "INCOMPASS: IMD Doppler radar convective cell statistics" } }, { "ob_id": 12398, "platform": { "ob_id": 31866, "uuid": "779b90c9ac2b4f689fe66be61b3bf381", "short_code": "plat", "title": "Mumbai", "abstract": "Mumbai, Chhatrapati Shivaji International Airport" }, "instrument": { "ob_id": 14231, "uuid": "490b4a087f734478a243eb9fc5b31a9e", "short_code": "instr", "title": "Doppler radars", "abstract": "A Doppler radar is a specialized radar that uses the Doppler effect to produce velocity data about objects at a distance. It does this by bouncing a microwave signal off a desired target and analyzing how the object's motion has altered the frequency of the returned signal. This variation gives direct and highly accurate measurements of the radial component of a target's velocity relative to the radar. " }, "relatedTo": { "ob_id": 31867, "uuid": "97840d9e49794b6aad67ac7aebd76272", "short_code": "acq", "title": "INCOMPASS: IMD Doppler radar convective cell statistics", "abstract": "INCOMPASS: IMD Doppler radar convective cell statistics" } } ] }, { "ob_id": 31871, "uuid": "11a725a0f1ef40acb5cbe4b619505ba8", "short_code": "acq", "title": "APHH: Ionic species data within PM2.5 measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Ionic species data within PM2.5 measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12399, "platform": { "ob_id": 30219, "uuid": "07a71f4e62e2468391f492b85905167c", "short_code": "plat", "title": "Indira Gandhi Delhi Technical University for Women (IGDTUW)", "abstract": "Indira Gandhi Delhi Technical University for Women (IGDTUW) which is situated on the periphery of Old Delhi and overlooks a very heavily populated area. As part of the DelhiFlux project the team have constructed a rooftop mast at 4m and a 30 m tall flux tower from which to directly measure pollutant emissions from two contrasting regions of Delhi." }, "instrument": { "ob_id": 27168, "uuid": "d90c2ff4219441f78ecdea981a33ed36", "short_code": "instr", "title": "University of York High Volume Sampler (Ecotech 3000, Australia)", "abstract": "The HiVol 3000 particulate sampler performs remote unattended sampling of PM2.5, PM10 or TSP along with basic meteorological parameters." }, "relatedTo": { "ob_id": 31871, "uuid": "11a725a0f1ef40acb5cbe4b619505ba8", "short_code": "acq", "title": "APHH: Ionic species data within PM2.5 measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Ionic species data within PM2.5 measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018" } }, { "ob_id": 12400, "platform": { "ob_id": 30219, "uuid": "07a71f4e62e2468391f492b85905167c", "short_code": "plat", "title": "Indira Gandhi Delhi Technical University for Women (IGDTUW)", "abstract": "Indira Gandhi Delhi Technical University for Women (IGDTUW) which is situated on the periphery of Old Delhi and overlooks a very heavily populated area. As part of the DelhiFlux project the team have constructed a rooftop mast at 4m and a 30 m tall flux tower from which to directly measure pollutant emissions from two contrasting regions of Delhi." }, "instrument": { "ob_id": 27169, "uuid": "f104d5769a8543dca6c2c90dde6e18a6", "short_code": "instr", "title": "University of York Dionex ICS-1100 Ion Chromatography System", "abstract": "The Thermo Scientific Dionex ICS-1100 Ion Chromatography System (Dionex ICS-1100) performs ion analyses using suppressed or non-suppressed conductivity detection. An ion chromatography system typically consists of a liquid eluent, a high-pressure pump, a sample injector, a guard and separator column, a chemical suppressor, a conductivity cell, and a data collection system." }, "relatedTo": { "ob_id": 31871, "uuid": "11a725a0f1ef40acb5cbe4b619505ba8", "short_code": "acq", "title": "APHH: Ionic species data within PM2.5 measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Ionic species data within PM2.5 measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018" } } ] }, { "ob_id": 31875, "uuid": "ca5b979b19204cb19c7865ace44b6328", "short_code": "acq", "title": "Aquisition for ESA Greenhouse Gases Climate Change Initiative (GHG_cci): Column-averaged carbon dioxide from TANSAT, generated with the OCFP algorithm, version 1.0", "abstract": "Aquisition for ESA Greenhouse Gases Climate Change Initiative (GHG_cci): Column-averaged carbon dioxide from TANSAT, generated with the OCFP algorithm, version 1.0", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12401, "platform": { "ob_id": 31876, "uuid": "184c930b206744e8b80321dd9024af64", "short_code": "plat", "title": "TANSAT", "abstract": "The TANSAT Satellite (Full name: Exploratory Satellite for Atmospheric CO2) is a Chinese satellite dedicated to the measurment of Atmospheric CO2. It was launched in December 2016." }, "instrument": { "ob_id": 31877, "uuid": "57fe77686e4f4e64b42b48617e726410", "short_code": "instr", "title": "ACGS", "abstract": "The Atmospheric Carbon-dioxide Grating Spectrometer (ACGS) is one of the instruments on the Chinese TANSAT satellite. It is a three-band NIR / SWIR grating spectroradiometer designed for the measurement of total-column CO2." }, "relatedTo": { "ob_id": 31875, "uuid": "ca5b979b19204cb19c7865ace44b6328", "short_code": "acq", "title": "Aquisition for ESA Greenhouse Gases Climate Change Initiative (GHG_cci): Column-averaged carbon dioxide from TANSAT, generated with the OCFP algorithm, version 1.0", "abstract": "Aquisition for ESA Greenhouse Gases Climate Change Initiative (GHG_cci): Column-averaged carbon dioxide from TANSAT, generated with the OCFP algorithm, version 1.0" } } ] }, { "ob_id": 31880, "uuid": "2a4d32750386446894e7da60d92d401d", "short_code": "acq", "title": "Iceland Greenland seas Project (IGP): Meteorological Buoy Measurements", "abstract": "Iceland Greenland seas Project (IGP): Meteorological Buoy Measurements", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12402, "platform": { "ob_id": 31882, "uuid": "c666fb3d29f040f98ce4ae30db74bf50", "short_code": "plat", "title": "Northwest Iceland Sea - Eggvin Offset", "abstract": "Location of SEAWATCH Wavescan Buoy adjacent to subsurface mooring in hte Eggvin Offset. Used in the Iceland Greenland seas Project (IGP)" }, "instrument": { "ob_id": 31881, "uuid": "f115f2e2014a47a7a6449b2ad581570d", "short_code": "instr", "title": "SEAWATCH Wavescan buoy", "abstract": "Measures standard meteorological variables, sea surface temperature, surface ocean currents and wave height, direction and period." }, "relatedTo": { "ob_id": 31880, "uuid": "2a4d32750386446894e7da60d92d401d", "short_code": "acq", "title": "Iceland Greenland seas Project (IGP): Meteorological Buoy Measurements", "abstract": "Iceland Greenland seas Project (IGP): Meteorological Buoy Measurements" } } ] }, { "ob_id": 31950, "uuid": "2bab7d6879dc408db2d2a54d2bb2673b", "short_code": "acq", "title": "NCAS-Xband radar longterm measurements from 08/11/2016-24/05/2018 at Chilbolton", "abstract": "NCAS-Xband radar longterm measurements from 08/11/2016-24/05/2018 at Chilbolton Observatory", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12403, "platform": { "ob_id": 817, "uuid": "0d60dd064b6449b09f5c7fd4c41bd693", "short_code": "plat", "title": "NCAS Chilbolton Atmospheric Observatory (CAO)", "abstract": "The National Centre for Atmospheric Science's Chilbolton Atmospheric Observatory, formerly known as the Chilbolton Facility for Atmospheric and Radio Research (CFARR), is hosted by the Science and Technology Facilities Council (STFC) in rural Hampshire in the South of England. Through a combination of long-term observations and tailored operations it provides national capability for the study of clouds, rainfall, boundary-layer processes and aerosols, and is particularly well suited as a site for hosting field campaigns involving visiting instruments.\r\n\r\nThe CAO site is located one mile south of Chilbolton Village, 6 miles south of Andover, Hampshire. The site was used as an airfield during the Second World War and is relatively flat and slightly elevated above the surrounding area.\r\n\r\nThe observatory operates more than twenty major instruments, many continuously, while others are available on-demand according to user configuration requirements. The portfolio includes a powerful combination of dual-polarisation Doppler radars, lidars, radiometers, and supporting instruments; the continuous round-the-clock operation of lidar and cloud radar instruments at Chilbolton is unique within the UK. These are supplemented by a suite of meteorological instrumentation including rain gauges, and disdrometers. A multi-wavelength sun photometer provides continuous measurements of aerosol optical depth in clear skies, and contributes to the Aerosol Robotic Network (AERONET).\r\n\r\nThe Chilbolton Advanced Meteorological Radar (CAMRa) is mounted on a 25-metre, fully steerable antenna, and is able to probe clouds and storms with unparalleled sensitivity and resolution. In addition, zenith-pointing polarimetric, Doppler 35 GHz and 94 GHz cloud radars are routinely operated for detailed microphysical studies of cloud processes and cloud climatology. A transportable, scanning 35 GHz cloud radar system is also hosted at Chilbolton, further enhancing the available capability.\r\n\r\nChilbolton was one of the pilot cloud profiling sites for the CLOUDNET project, and continues to make observations that feed into the Aerosol Clouds and Trace Gases Research Infrastructure (ACTRIS). Capability at the site will be enhanced in the next few years, with the incorporation of a Raman lidar, with the ambition being for this to form an ACTRIS observational platform for aerosol profiling.\r\n\r\nThe presence (since January 2016) of a Defra air quality monitoring supersite at the observatory site (providing rural background measurements as part of national and transboundary networks) offers the research community further excellent opportunities for intercomparison campaigns and instrument evaluation.\r\n\r\nWIGOS id: \r\n0-826-300-3\r\n0-826-300-4\r\n0-826-300-5\r\n\r\nThe Met Office also operated a boundary layer wind profiler at the site (now operated by NCAS AMOF), for which the site was given a WMO ID 03754." }, "instrument": { "ob_id": 12250, "uuid": "792da2ff61f647aa8021b4b9c06702a9", "short_code": "instr", "title": "NCAS Atmospheric Measurement Facility's (AMOF) mobile X-band radar 1", "abstract": "The National Centre for Atmospheric Science Atmospheric Measurement Facility's (NCAS AMOF) mobile X-band radar operates in the X-band (frequency = 9.375 GHz, wavelength = 3 cm). It has Doppler and dual-polarisation capability. The radar measures the location and intensity of precipitation, radial winds and polarisation parameters. It works by transmitting pulses of electromagnetic radiation and measuring the amount of energy backscattered to the receiver. The time delay between the transmitted and received pulses enables the range of the object to be determined. In the case of precipitation, the magnitude of the backscattered signal is proportional to the size and number of raindrops. The radar also measures the radial velocity through the Doppler effect. In the absence of precipitation, the radar is sensitive to backscattering from insects, known as clear-air echoes, at close range. These signals provide information on the wind field and the organisation of the boundary-layer e.g. features such as convergence lines can be identified. In addition, the radar has dual-polarisation capability; it simultaneously transmits and receives horizontally- and vertically- polarised waves. Through this technique the radar measures a number of additional variables that provide information on the size and shape of precipitation, identification of non-meteorological echoes, attenuation (a decrease in the signal strength due to the absorption and scattering of the radar signal as it propagates through heavy rain), and alternative methods for calculating rainfall rates. \r\n\r\nThe system has a conventional parabolic antenna of 2.4m diameter and a beamwidth of 1 degree (in the horizontal and vertical), and is operated without a radome. The range resolution is tunable and dependent on the user-selected pulse width (0.5, 1 or 2 micro seconds) and pulse repetition frequency (PRF, 250-2000 Hz). The radar is fully transportable, being mounted on a trailer approved for EU roads that can be towed by a 4x4 vehicle. Signal analysis, data retrievals and data storage are performed by PCs contained within the trailer unit. The radar can be operated via a laptop that connects by wireless, ethernet or 3G to the onboard PCs. The operational software allows the user to set up the radar for deployment and schedule the scanning sequence. The software also provides real-time data visualisation and product generation.\r\n\r\nThe data frequency is dependant on the requirements for the instrument's deployment, but is typically of the order of 10 360-degree scans at various elevations every 5 minutes.\r\n\r\nParameters available in data files from this instrument include: \r\nDOP - degree of polarization; \r\nKDP - specific differential phase shift; \r\nPhiDP - differential phase shift; \r\nRhoHV - co-polar cross correlation coefficient; \r\nSQI - signal quality index or normalized_coherent_power; \r\nV - radial velocity; \r\nW - spectral width; \r\nZDR - differential reflectivity; \r\ndBZ - reflectivity or equivalent reflectivity factor." }, "relatedTo": { "ob_id": 31950, "uuid": "2bab7d6879dc408db2d2a54d2bb2673b", "short_code": "acq", "title": "NCAS-Xband radar longterm measurements from 08/11/2016-24/05/2018 at Chilbolton", "abstract": "NCAS-Xband radar longterm measurements from 08/11/2016-24/05/2018 at Chilbolton Observatory" } } ] }, { "ob_id": 31953, "uuid": "1a4fe170b116409bb7177cb098b7cb8f", "short_code": "acq", "title": "Acquisition for the ESA Climate Change Initiative Sea Level altimeter coastal sea level anomalies datasets", "abstract": "Acquisition for the ESA Climate Change Initiative Sea Level altimeter coastal sea level anomalies datasets", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12404, "platform": { "ob_id": 30018, "uuid": "dc9445f2ebc5410cb39df2984165c52b", "short_code": "plat", "title": "JASON-1", "abstract": "The JASON-1 (Joint Altimetery Satellite Oceanography Network - 1) satellite was the first flight of the JASON series of satellites, with a primary mission to study ocean topography and waves. It flew between December 2001 and July 2013" }, "instrument": { "ob_id": 30019, "uuid": "64d73638c9a14a3fad59d6ae8658fd37", "short_code": "instr", "title": "Poseidon-2", "abstract": "The Poseidon-2 satellite instrument was flown on the JASON-1 satellite. It is a radar altimeter designed to study ocean topography, significant wave height and wind speed." }, "relatedTo": { "ob_id": 31953, "uuid": "1a4fe170b116409bb7177cb098b7cb8f", "short_code": "acq", "title": "Acquisition for the ESA Climate Change Initiative Sea Level altimeter coastal sea level anomalies datasets", "abstract": "Acquisition for the ESA Climate Change Initiative Sea Level altimeter coastal sea level anomalies datasets" } }, { "ob_id": 12405, "platform": { "ob_id": 30020, "uuid": "154dafa0c39d47beb7b1b8f29efa237f", "short_code": "plat", "title": "JASON-2", "abstract": "The JASON-2 (Joint Altimetry Satellite Oceanography Network -2 ) satellite was flown to study ocean topography and waves. It flew between June 2008 and October 2019" }, "instrument": { "ob_id": 30021, "uuid": "57297602ceef42edb983796ce9089963", "short_code": "instr", "title": "Poseidon-3", "abstract": "The Poseidon-3 instrument was flown on the JASON-2 satellite. It is a radar altimeter, designed to study ocean topography, significant wave height and wind speed." }, "relatedTo": { "ob_id": 31953, "uuid": "1a4fe170b116409bb7177cb098b7cb8f", "short_code": "acq", "title": "Acquisition for the ESA Climate Change Initiative Sea Level altimeter coastal sea level anomalies datasets", "abstract": "Acquisition for the ESA Climate Change Initiative Sea Level altimeter coastal sea level anomalies datasets" } }, { "ob_id": 12406, "platform": { "ob_id": 30022, "uuid": "40826d62fbe6438494c543d9284e7c61", "short_code": "plat", "title": "JASON-3", "abstract": "The JASON-3 (Joint Altimetry Satellite Oceanography Network - 3 ) Satellite was launched on Jan 2016. It primary mission is to study ocean topography and waves." }, "instrument": { "ob_id": 30023, "uuid": "fcdd312219c4443985a9a1708867500e", "short_code": "instr", "title": "Poseidon-3B", "abstract": "The Poseidon-3B satellite instrument is flying on the JASON-3 satellite. It is a radar altimeter, designed to study ocean topography, significant wave height and wind speed." }, "relatedTo": { "ob_id": 31953, "uuid": "1a4fe170b116409bb7177cb098b7cb8f", "short_code": "acq", "title": "Acquisition for the ESA Climate Change Initiative Sea Level altimeter coastal sea level anomalies datasets", "abstract": "Acquisition for the ESA Climate Change Initiative Sea Level altimeter coastal sea level anomalies datasets" } } ] }, { "ob_id": 32011, "uuid": "3b5a15073de0478ba33964ebb063ecb6", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v05.2", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments.", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 8209, "uuid": "f0f061d64cca41c3a4221b713fd6b1be", "short_code": "mpop", "title": "Mobile Platform Operation for: Metop-A", "abstract": "Mobile Platform Operation related to the: Metop-A" }, { "ob_id": 8301, "uuid": "d1d4ffcf747d4e95a3614aa20f1855da", "short_code": "mpop", "title": "Mobile Platform Operation for: Metop-B", "abstract": "Mobile Platform Operation related to the: Metop-B" }, { "ob_id": 7814, "uuid": "ae416a28a96049e7bf33ea668c187852", "short_code": "mpop", "title": "Mobile Platform Operation for: ERS-2", "abstract": "Mobile Platform Operation related to the: ERS-2" }, { "ob_id": 7807, "uuid": "a27cd0df0a124f2ca5873877e21f637e", "short_code": "mpop", "title": "Mobile Platform Operation for: ERS-1", "abstract": "Mobile Platform Operation related to the: ERS-1" } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12407, "platform": { "ob_id": 8207, "uuid": "3f2dbe69fe4c40ee9e1e8be87e15a1d5", "short_code": "plat", "title": "Metop-A", "abstract": "Metop-A, launched on 19 October 2006, represents the first in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS). Metop-A is Europe's first polar-orbiting meteorological satellite" }, "instrument": { "ob_id": 27121, "uuid": "ca133e0771514003a9e7c2462c1b363c", "short_code": "instr", "title": "ASCAT", "abstract": "ASCAT (Advanced Scatterometer) is a C Band (2.55 GHz) Scatterometer flown on the Metop series of satellites. It measures the sea surface wind vecotr and large-scale soil moisture." }, "relatedTo": { "ob_id": 32011, "uuid": "3b5a15073de0478ba33964ebb063ecb6", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v05.2", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments." } }, { "ob_id": 12408, "platform": { "ob_id": 8299, "uuid": "84a6355ac58249cc8c636e77a243c86a", "short_code": "plat", "title": "Metop-B", "abstract": "Metop-B, launched on the 17th September 2012, is the second in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS)." }, "instrument": { "ob_id": 27121, "uuid": "ca133e0771514003a9e7c2462c1b363c", "short_code": "instr", "title": "ASCAT", "abstract": "ASCAT (Advanced Scatterometer) is a C Band (2.55 GHz) Scatterometer flown on the Metop series of satellites. It measures the sea surface wind vecotr and large-scale soil moisture." }, "relatedTo": { "ob_id": 32011, "uuid": "3b5a15073de0478ba33964ebb063ecb6", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v05.2", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments." } }, { "ob_id": 12409, "platform": { "ob_id": 7805, "uuid": "d21630e98aa74a4f8406743b74e5d076", "short_code": "plat", "title": "ERS-1", "abstract": "The European Remote Sensing satellite 1 (ERS1) was launched on 17th July 1991 and was the first flight of the RSA ERS program. The payload included the ATSR, AMU-SAR , AMI-SCAT, LRR PRARE and RA instruments. End of mission for ERS1 was 10th March 2000." }, "instrument": { "ob_id": 27122, "uuid": "7b488736a173477689480990d5b38aa9", "short_code": "instr", "title": "AMI-SCAT", "abstract": "AMI-SCAT (Active Microwave Instrument - Scatterometer) is a C-band (5.3 GHz) scatterometer flying on the ERS-1 and ERS-2 satellites. It measures the sea surface wind vector and large-scale soil moisture." }, "relatedTo": { "ob_id": 32011, "uuid": "3b5a15073de0478ba33964ebb063ecb6", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v05.2", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments." } }, { "ob_id": 12410, "platform": { "ob_id": 7813, "uuid": "8ee876e1ea644ed7a81d4e3536133fa0", "short_code": "plat", "title": "European Remote Sensing satellite 2 - ERS-2", "abstract": "ESA's two European Remote Sensing (ERS) satellites, ERS-1 and –2, were launched into the same orbit in 1991 and 1995 respectively. Their payloads included a synthetic aperture imaging radar, radar altimeter and instruments to measure ocean surface temperature and wind fields.\r\n\r\nERS-2 added an additional sensor for atmospheric ozone monitoring. The two satellites acquired a combined data set extending over two decades.\r\n\r\nThe ERS-2 satellite was retired on 05 September 2011." }, "instrument": { "ob_id": 27122, "uuid": "7b488736a173477689480990d5b38aa9", "short_code": "instr", "title": "AMI-SCAT", "abstract": "AMI-SCAT (Active Microwave Instrument - Scatterometer) is a C-band (5.3 GHz) scatterometer flying on the ERS-1 and ERS-2 satellites. It measures the sea surface wind vector and large-scale soil moisture." }, "relatedTo": { "ob_id": 32011, "uuid": "3b5a15073de0478ba33964ebb063ecb6", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v05.2", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments." } } ] }, { "ob_id": 32012, "uuid": "8e5d8bc49927483286faa5929e012d72", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.2", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments.", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 27137, "uuid": "f6550c6efe0c4a9baaf3c5d07627b2ed", "short_code": "mpop", "title": "GCOM-W satellite orbit details", "abstract": "The GCOM-W (Global Change Observation Mission for Water) is a JAXA satellite in a sunsynchronous orbit with a 13.30 ascending equator crossing time." }, { "ob_id": 27138, "uuid": "44f2493522254d2696575ce3acb6146c", "short_code": "mpop", "title": "TRMM satellite orbit details", "abstract": "The TRMM (Tropical Rainfall Measuring Mission) is a NASA, JAXA satellite mission. It is in a drifting orbit with an inclination of 35 degrees and altitude of 402 km." }, { "ob_id": 2631, "uuid": "4647e36325d544eca3db5d8795c216c6", "short_code": "mpop", "title": "Mobile Platform Operation for: Defense Meteorological Satellite Program (DMSP) Satellites", "abstract": "Mobile Platform Operation related to the: Defense Meteorological Satellite Program (DMSP) Satellites" }, { "ob_id": 460, "uuid": "bea2c6443d2f4f81a2701f09cb4e6f5c", "short_code": "mpop", "title": "Mobile Platform Operation for: NIMBUS 7 Satellite", "abstract": "Mobile Platform Operation related to the: NIMBUS 7 Satellite" }, { "ob_id": 10907, "uuid": "1be652a219874193976dff38a64fc180", "short_code": "mpop", "title": "Aqua Satellite orbit details", "abstract": "NASA's AQUA (EOS-PM1) is a sun-synchronous, polar orbiting satellite in an afternoon orbit, with equator crossing times of approximately 13:30 and 01:30. It forms part of the A-train, a collection of satellites orbiting close together along the same orbital track" }, { "ob_id": 27132, "uuid": "6c74884699f541ff8a1edb33933ddada", "short_code": "mpop", "title": "Coriolis Satellite Orbit Details", "abstract": "The Coriolis Satellite is flown by NASA and the US Department of Defence and is in a Sunsynchronous orbit with an 06.10 descending equator crossing time." }, { "ob_id": 27133, "uuid": "c15fb49dfbf24bdc81acb5ae16df1b1d", "short_code": "mpop", "title": "SMOS satellite orbit details", "abstract": "The SMOS satellite is operated by ESA and is in a sunscynchronous orbit with a 06:00 ascending equator crossing time." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12411, "platform": { "ob_id": 458, "uuid": "b6d87ac1455348cd97a4386b38995dbb", "short_code": "plat", "title": "NIMBUS 7 Satellite", "abstract": "The NASA Nimbus 7 research-and-development polar-orbiting satellite served as a stabilized, earth-oriented platform for the testing of advanced systems for sensing and collecting data in the pollution, oceanographic and meteorological disciplines. It was launched on October 24, 1978." }, "instrument": { "ob_id": 2636, "uuid": "1578228cc3cf4b9fba0b88c61b58800b", "short_code": "instr", "title": "Scanning Multichannel Microwave Radiometer (SMMR)", "abstract": "The Scanning Multichannel Microwave Radiometer operated on NASA's Nimbus-7 satellite for more than eight years, from 26 October 1978 to 20 August 1987, transmitting data every other day. Intended to obtain ocean circulation parameters such as sea surface temperatures, low altitude winds, water vapor and cloud liquid water content on an all-weather basis, the SMMR is a ten channel instrument capable of receiving both horizontally and vertically polarized radiation. A parabolic antenna 79 cm in diameter reflected microwave emissions into a five-frequency feed horn. The antenna beam maintained a constant nadir angle of 42 degrees, resulting in an incidence angle of 50.3 degrees at Earth's surface. The antenna was forward viewing and rotated equally +/- 25 degrees about the satellite subtrack. The 50 degree scan provided a 780 km swath of the Earth's surface. Scan period was 4.096 seconds." }, "relatedTo": { "ob_id": 32012, "uuid": "8e5d8bc49927483286faa5929e012d72", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.2", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12412, "platform": { "ob_id": 2629, "uuid": "9f1b0a2380cc47919b201880e0fee6de", "short_code": "plat", "title": "Defense Meteorological Satellite Program (DMSP) Satellites", "abstract": "DMSP satellites are used for strategic and tactical weather prediction to aid the U.S. military in planning operations at sea, on land and in the air. Equipped with a sophisticated sensor suite that can image visible and infrared cloud cover and measure precipitation, surface temperature, and soil moisture, the satellite collects specialized global meteorological, oceanographic, and solar-geophysical information in all weather conditions. The DMSP constellation comprises two spacecraft in near-polar orbits, C3 (command, control and communications), user terminals and weather centers." }, "instrument": { "ob_id": 2630, "uuid": "54f897597ec04c09b01095eb05c7419e", "short_code": "instr", "title": "Special Sensor Microwave / Imager (SSM/I)", "abstract": "The SSM/I is a seven-channel, four frequency, linearly-polarized, passive microwave radiometric system which measures atmospheric, ocean and terrain microwave brightness temperatures at 19.35, 22.235, 37.0 and 85.5 GHz. The data are used to obtain synoptic maps of critical atmospheric, oceanographic and selected land parameters on a global scale." }, "relatedTo": { "ob_id": 32012, "uuid": "8e5d8bc49927483286faa5929e012d72", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.2", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12413, "platform": { "ob_id": 27135, "uuid": "8afe985a2f3f4b15aaa52df6119c0f27", "short_code": "plat", "title": "TRMM", "abstract": "The Tropical Rainfall Measuring Mission (TRMM) is a NASA and JAXA satellite that flew between 1997 and 2015. It's primary mission was to measure precipitation." }, "instrument": { "ob_id": 27126, "uuid": "9173171ba44845e9a873e21b4dee19e2", "short_code": "instr", "title": "TMI", "abstract": "TMI (TRMM Microwave Imager) is a multi-purpose microwave imager flying on the TRMM (Tropical Rainfall Measuring Mission)." }, "relatedTo": { "ob_id": 32012, "uuid": "8e5d8bc49927483286faa5929e012d72", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.2", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12414, "platform": { "ob_id": 10906, "uuid": "5a1076bffc8c4c5d8a2ff3a4cfb29846", "short_code": "plat", "title": "Aqua Satellite, part of the Earth Observation System Afternoon Constellation (EOS-PM)", "abstract": "Aqua, launched on 4th April 2002, is a polar-orbiting satellite within the Afternoon Constellation (A-Train) that have equator crossings around 13:30 and 01:30 under NASA's Earth Obseration System (EOS). The satellite carries Atmospheric Infrared Sounder (AIRS), Advanced Microwave Sounding Unit (AMSU-A), Humidity Sounder for Brazil (HSB), Advanced Microwave Scanning Radiometer for EOS (AMSR-E), Moderate-Resolution Imaging Spectroradiometer (MODIS) and Clouds and the Earth's Radiant Energy System (CERES), and these collect data on the Earth's atmospheric conditions, snow and ice, sea surface temperature and ocean productivity, and soil moisture. Aqua was the first member launched of a group of satellites termed the Afternoon Constellation, or sometimes the A-Train. " }, "instrument": { "ob_id": 14485, "uuid": "77dd26fc341a440b85a98fe95b1976f8", "short_code": "instr", "title": "AMSR-E", "abstract": "Advanced Microwave Scanning Radiometer for EOS" }, "relatedTo": { "ob_id": 32012, "uuid": "8e5d8bc49927483286faa5929e012d72", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.2", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12415, "platform": { "ob_id": 25273, "uuid": "f10d619f7b9f4dbab792dcc1ab9dbb68", "short_code": "plat", "title": "GCOM-W (Global Change Observation Mission for Water)", "abstract": "The Global Change Observation Mission for Water (GCOM-W) is a series of three satellites flown by the Japanese Space Agency (JAXA), addressing multi-purpose MW imagery for ocean, land and precipitation. It is part of their Global Change Observation Mission (GCOM).\r\nThe satellites exploit sun-synchronous orbits around 13:30, coordinated with that of POES satellites, Suomi-NPP and JPSS." }, "instrument": { "ob_id": 25272, "uuid": "a6002da7c0954ce0aa146c1b24877a0a", "short_code": "instr", "title": "AMSR-2", "abstract": "Advanced Microwave Scanning Radiometer -2, flying on the Global Change Observation Mission (GCOM) series of satellites flown by JAXA" }, "relatedTo": { "ob_id": 32012, "uuid": "8e5d8bc49927483286faa5929e012d72", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.2", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12416, "platform": { "ob_id": 27130, "uuid": "526c6fb02e094d049d367aaa4f79e8d1", "short_code": "plat", "title": "Coriolis", "abstract": "The Coriolis satellite is flown by NASA and the US Department of Defence, with a primary mission to provide observations of the sea-surface wind. It carries two instruments: WindSat and SMEI (Solar Mass Ejection Imager)" }, "instrument": { "ob_id": 27125, "uuid": "10f4aca379f84e0cae56392a85604469", "short_code": "instr", "title": "WindSat", "abstract": "WindSat is a passive microwave radiometer flown on the Coriolis Satellite by the US Department of Defence since 2003." }, "relatedTo": { "ob_id": 32012, "uuid": "8e5d8bc49927483286faa5929e012d72", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.2", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12417, "platform": { "ob_id": 27128, "uuid": "9c6e8c73f539446ba7a8adef871492a7", "short_code": "plat", "title": "SMOS", "abstract": "The SMOS (Soil Moisture and Ocean Salinity) satellite was launched on Novermber 2009, with the primary mission to monitor ocean salinity and soil moisture." }, "instrument": { "ob_id": 27124, "uuid": "9b4be0d67030450ca8aebf37cf39500c", "short_code": "instr", "title": "MIRAS", "abstract": "MIRAS (Microwave Imaging Radiometer using Aperture Synthesis) is an European Space Agency instrument flown on the SMOS (Soil Moisture and Ocean Salinity) Satellite. It measures Ocean Salinity and Soil Moisture." }, "relatedTo": { "ob_id": 32012, "uuid": "8e5d8bc49927483286faa5929e012d72", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.2", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12429, "platform": { "ob_id": 29941, "uuid": "2b126b39dbb64c0681f12b68f2308fee", "short_code": "plat", "title": "SMAP", "abstract": "The Soil Moisture Active-Passive (SMAP) satelliteis a NASA satellite launched in 2015." }, "instrument": { "ob_id": 29938, "uuid": "e050ad22e3b943f9a5f1563a1e6fb82c", "short_code": "instr", "title": "SMAP", "abstract": "The Soil Moisture Active Passive instrument is a microwave radiometer flown on the NASA SMAP satellite." }, "relatedTo": { "ob_id": 32012, "uuid": "8e5d8bc49927483286faa5929e012d72", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.2", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } } ] }, { "ob_id": 32013, "uuid": "99251b53c2e84901b4bf6ec6fd78ad51", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.2", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 460, "uuid": "bea2c6443d2f4f81a2701f09cb4e6f5c", "short_code": "mpop", "title": "Mobile Platform Operation for: NIMBUS 7 Satellite", "abstract": "Mobile Platform Operation related to the: NIMBUS 7 Satellite" }, { "ob_id": 2631, "uuid": "4647e36325d544eca3db5d8795c216c6", "short_code": "mpop", "title": "Mobile Platform Operation for: Defense Meteorological Satellite Program (DMSP) Satellites", "abstract": "Mobile Platform Operation related to the: Defense Meteorological Satellite Program (DMSP) Satellites" }, { "ob_id": 10907, "uuid": "1be652a219874193976dff38a64fc180", "short_code": "mpop", "title": "Aqua Satellite orbit details", "abstract": "NASA's AQUA (EOS-PM1) is a sun-synchronous, polar orbiting satellite in an afternoon orbit, with equator crossing times of approximately 13:30 and 01:30. It forms part of the A-train, a collection of satellites orbiting close together along the same orbital track" }, { "ob_id": 27132, "uuid": "6c74884699f541ff8a1edb33933ddada", "short_code": "mpop", "title": "Coriolis Satellite Orbit Details", "abstract": "The Coriolis Satellite is flown by NASA and the US Department of Defence and is in a Sunsynchronous orbit with an 06.10 descending equator crossing time." }, { "ob_id": 27133, "uuid": "c15fb49dfbf24bdc81acb5ae16df1b1d", "short_code": "mpop", "title": "SMOS satellite orbit details", "abstract": "The SMOS satellite is operated by ESA and is in a sunscynchronous orbit with a 06:00 ascending equator crossing time." }, { "ob_id": 27137, "uuid": "f6550c6efe0c4a9baaf3c5d07627b2ed", "short_code": "mpop", "title": "GCOM-W satellite orbit details", "abstract": "The GCOM-W (Global Change Observation Mission for Water) is a JAXA satellite in a sunsynchronous orbit with a 13.30 ascending equator crossing time." }, { "ob_id": 27138, "uuid": "44f2493522254d2696575ce3acb6146c", "short_code": "mpop", "title": "TRMM satellite orbit details", "abstract": "The TRMM (Tropical Rainfall Measuring Mission) is a NASA, JAXA satellite mission. It is in a drifting orbit with an inclination of 35 degrees and altitude of 402 km." }, { "ob_id": 8209, "uuid": "f0f061d64cca41c3a4221b713fd6b1be", "short_code": "mpop", "title": "Mobile Platform Operation for: Metop-A", "abstract": "Mobile Platform Operation related to the: Metop-A" }, { "ob_id": 8301, "uuid": "d1d4ffcf747d4e95a3614aa20f1855da", "short_code": "mpop", "title": "Mobile Platform Operation for: Metop-B", "abstract": "Mobile Platform Operation related to the: Metop-B" }, { "ob_id": 7814, "uuid": "ae416a28a96049e7bf33ea668c187852", "short_code": "mpop", "title": "Mobile Platform Operation for: ERS-2", "abstract": "Mobile Platform Operation related to the: ERS-2" }, { "ob_id": 7807, "uuid": "a27cd0df0a124f2ca5873877e21f637e", "short_code": "mpop", "title": "Mobile Platform Operation for: ERS-1", "abstract": "Mobile Platform Operation related to the: ERS-1" } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12418, "platform": { "ob_id": 27128, "uuid": "9c6e8c73f539446ba7a8adef871492a7", "short_code": "plat", "title": "SMOS", "abstract": "The SMOS (Soil Moisture and Ocean Salinity) satellite was launched on Novermber 2009, with the primary mission to monitor ocean salinity and soil moisture." }, "instrument": { "ob_id": 27124, "uuid": "9b4be0d67030450ca8aebf37cf39500c", "short_code": "instr", "title": "MIRAS", "abstract": "MIRAS (Microwave Imaging Radiometer using Aperture Synthesis) is an European Space Agency instrument flown on the SMOS (Soil Moisture and Ocean Salinity) Satellite. It measures Ocean Salinity and Soil Moisture." }, "relatedTo": { "ob_id": 32013, "uuid": "99251b53c2e84901b4bf6ec6fd78ad51", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.2", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12419, "platform": { "ob_id": 27130, "uuid": "526c6fb02e094d049d367aaa4f79e8d1", "short_code": "plat", "title": "Coriolis", "abstract": "The Coriolis satellite is flown by NASA and the US Department of Defence, with a primary mission to provide observations of the sea-surface wind. It carries two instruments: WindSat and SMEI (Solar Mass Ejection Imager)" }, "instrument": { "ob_id": 27125, "uuid": "10f4aca379f84e0cae56392a85604469", "short_code": "instr", "title": "WindSat", "abstract": "WindSat is a passive microwave radiometer flown on the Coriolis Satellite by the US Department of Defence since 2003." }, "relatedTo": { "ob_id": 32013, "uuid": "99251b53c2e84901b4bf6ec6fd78ad51", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.2", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12420, "platform": { "ob_id": 25273, "uuid": "f10d619f7b9f4dbab792dcc1ab9dbb68", "short_code": "plat", "title": "GCOM-W (Global Change Observation Mission for Water)", "abstract": "The Global Change Observation Mission for Water (GCOM-W) is a series of three satellites flown by the Japanese Space Agency (JAXA), addressing multi-purpose MW imagery for ocean, land and precipitation. It is part of their Global Change Observation Mission (GCOM).\r\nThe satellites exploit sun-synchronous orbits around 13:30, coordinated with that of POES satellites, Suomi-NPP and JPSS." }, "instrument": { "ob_id": 25272, "uuid": "a6002da7c0954ce0aa146c1b24877a0a", "short_code": "instr", "title": "AMSR-2", "abstract": "Advanced Microwave Scanning Radiometer -2, flying on the Global Change Observation Mission (GCOM) series of satellites flown by JAXA" }, "relatedTo": { "ob_id": 32013, "uuid": "99251b53c2e84901b4bf6ec6fd78ad51", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.2", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12421, "platform": { "ob_id": 10906, "uuid": "5a1076bffc8c4c5d8a2ff3a4cfb29846", "short_code": "plat", "title": "Aqua Satellite, part of the Earth Observation System Afternoon Constellation (EOS-PM)", "abstract": "Aqua, launched on 4th April 2002, is a polar-orbiting satellite within the Afternoon Constellation (A-Train) that have equator crossings around 13:30 and 01:30 under NASA's Earth Obseration System (EOS). The satellite carries Atmospheric Infrared Sounder (AIRS), Advanced Microwave Sounding Unit (AMSU-A), Humidity Sounder for Brazil (HSB), Advanced Microwave Scanning Radiometer for EOS (AMSR-E), Moderate-Resolution Imaging Spectroradiometer (MODIS) and Clouds and the Earth's Radiant Energy System (CERES), and these collect data on the Earth's atmospheric conditions, snow and ice, sea surface temperature and ocean productivity, and soil moisture. Aqua was the first member launched of a group of satellites termed the Afternoon Constellation, or sometimes the A-Train. " }, "instrument": { "ob_id": 14485, "uuid": "77dd26fc341a440b85a98fe95b1976f8", "short_code": "instr", "title": "AMSR-E", "abstract": "Advanced Microwave Scanning Radiometer for EOS" }, "relatedTo": { "ob_id": 32013, "uuid": "99251b53c2e84901b4bf6ec6fd78ad51", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.2", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12422, "platform": { "ob_id": 27135, "uuid": "8afe985a2f3f4b15aaa52df6119c0f27", "short_code": "plat", "title": "TRMM", "abstract": "The Tropical Rainfall Measuring Mission (TRMM) is a NASA and JAXA satellite that flew between 1997 and 2015. It's primary mission was to measure precipitation." }, "instrument": { "ob_id": 27126, "uuid": "9173171ba44845e9a873e21b4dee19e2", "short_code": "instr", "title": "TMI", "abstract": "TMI (TRMM Microwave Imager) is a multi-purpose microwave imager flying on the TRMM (Tropical Rainfall Measuring Mission)." }, "relatedTo": { "ob_id": 32013, "uuid": "99251b53c2e84901b4bf6ec6fd78ad51", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.2", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12423, "platform": { "ob_id": 2629, "uuid": "9f1b0a2380cc47919b201880e0fee6de", "short_code": "plat", "title": "Defense Meteorological Satellite Program (DMSP) Satellites", "abstract": "DMSP satellites are used for strategic and tactical weather prediction to aid the U.S. military in planning operations at sea, on land and in the air. Equipped with a sophisticated sensor suite that can image visible and infrared cloud cover and measure precipitation, surface temperature, and soil moisture, the satellite collects specialized global meteorological, oceanographic, and solar-geophysical information in all weather conditions. The DMSP constellation comprises two spacecraft in near-polar orbits, C3 (command, control and communications), user terminals and weather centers." }, "instrument": { "ob_id": 2630, "uuid": "54f897597ec04c09b01095eb05c7419e", "short_code": "instr", "title": "Special Sensor Microwave / Imager (SSM/I)", "abstract": "The SSM/I is a seven-channel, four frequency, linearly-polarized, passive microwave radiometric system which measures atmospheric, ocean and terrain microwave brightness temperatures at 19.35, 22.235, 37.0 and 85.5 GHz. The data are used to obtain synoptic maps of critical atmospheric, oceanographic and selected land parameters on a global scale." }, "relatedTo": { "ob_id": 32013, "uuid": "99251b53c2e84901b4bf6ec6fd78ad51", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.2", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12424, "platform": { "ob_id": 458, "uuid": "b6d87ac1455348cd97a4386b38995dbb", "short_code": "plat", "title": "NIMBUS 7 Satellite", "abstract": "The NASA Nimbus 7 research-and-development polar-orbiting satellite served as a stabilized, earth-oriented platform for the testing of advanced systems for sensing and collecting data in the pollution, oceanographic and meteorological disciplines. It was launched on October 24, 1978." }, "instrument": { "ob_id": 2636, "uuid": "1578228cc3cf4b9fba0b88c61b58800b", "short_code": "instr", "title": "Scanning Multichannel Microwave Radiometer (SMMR)", "abstract": "The Scanning Multichannel Microwave Radiometer operated on NASA's Nimbus-7 satellite for more than eight years, from 26 October 1978 to 20 August 1987, transmitting data every other day. Intended to obtain ocean circulation parameters such as sea surface temperatures, low altitude winds, water vapor and cloud liquid water content on an all-weather basis, the SMMR is a ten channel instrument capable of receiving both horizontally and vertically polarized radiation. A parabolic antenna 79 cm in diameter reflected microwave emissions into a five-frequency feed horn. The antenna beam maintained a constant nadir angle of 42 degrees, resulting in an incidence angle of 50.3 degrees at Earth's surface. The antenna was forward viewing and rotated equally +/- 25 degrees about the satellite subtrack. The 50 degree scan provided a 780 km swath of the Earth's surface. Scan period was 4.096 seconds." }, "relatedTo": { "ob_id": 32013, "uuid": "99251b53c2e84901b4bf6ec6fd78ad51", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.2", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12425, "platform": { "ob_id": 8207, "uuid": "3f2dbe69fe4c40ee9e1e8be87e15a1d5", "short_code": "plat", "title": "Metop-A", "abstract": "Metop-A, launched on 19 October 2006, represents the first in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS). Metop-A is Europe's first polar-orbiting meteorological satellite" }, "instrument": { "ob_id": 27121, "uuid": "ca133e0771514003a9e7c2462c1b363c", "short_code": "instr", "title": "ASCAT", "abstract": "ASCAT (Advanced Scatterometer) is a C Band (2.55 GHz) Scatterometer flown on the Metop series of satellites. It measures the sea surface wind vecotr and large-scale soil moisture." }, "relatedTo": { "ob_id": 32013, "uuid": "99251b53c2e84901b4bf6ec6fd78ad51", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.2", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12426, "platform": { "ob_id": 8299, "uuid": "84a6355ac58249cc8c636e77a243c86a", "short_code": "plat", "title": "Metop-B", "abstract": "Metop-B, launched on the 17th September 2012, is the second in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS)." }, "instrument": { "ob_id": 27121, "uuid": "ca133e0771514003a9e7c2462c1b363c", "short_code": "instr", "title": "ASCAT", "abstract": "ASCAT (Advanced Scatterometer) is a C Band (2.55 GHz) Scatterometer flown on the Metop series of satellites. It measures the sea surface wind vecotr and large-scale soil moisture." }, "relatedTo": { "ob_id": 32013, "uuid": "99251b53c2e84901b4bf6ec6fd78ad51", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.2", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12427, "platform": { "ob_id": 7805, "uuid": "d21630e98aa74a4f8406743b74e5d076", "short_code": "plat", "title": "ERS-1", "abstract": "The European Remote Sensing satellite 1 (ERS1) was launched on 17th July 1991 and was the first flight of the RSA ERS program. The payload included the ATSR, AMU-SAR , AMI-SCAT, LRR PRARE and RA instruments. End of mission for ERS1 was 10th March 2000." }, "instrument": { "ob_id": 27122, "uuid": "7b488736a173477689480990d5b38aa9", "short_code": "instr", "title": "AMI-SCAT", "abstract": "AMI-SCAT (Active Microwave Instrument - Scatterometer) is a C-band (5.3 GHz) scatterometer flying on the ERS-1 and ERS-2 satellites. It measures the sea surface wind vector and large-scale soil moisture." }, "relatedTo": { "ob_id": 32013, "uuid": "99251b53c2e84901b4bf6ec6fd78ad51", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.2", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12428, "platform": { "ob_id": 7813, "uuid": "8ee876e1ea644ed7a81d4e3536133fa0", "short_code": "plat", "title": "European Remote Sensing satellite 2 - ERS-2", "abstract": "ESA's two European Remote Sensing (ERS) satellites, ERS-1 and –2, were launched into the same orbit in 1991 and 1995 respectively. Their payloads included a synthetic aperture imaging radar, radar altimeter and instruments to measure ocean surface temperature and wind fields.\r\n\r\nERS-2 added an additional sensor for atmospheric ozone monitoring. The two satellites acquired a combined data set extending over two decades.\r\n\r\nThe ERS-2 satellite was retired on 05 September 2011." }, "instrument": { "ob_id": 27122, "uuid": "7b488736a173477689480990d5b38aa9", "short_code": "instr", "title": "AMI-SCAT", "abstract": "AMI-SCAT (Active Microwave Instrument - Scatterometer) is a C-band (5.3 GHz) scatterometer flying on the ERS-1 and ERS-2 satellites. It measures the sea surface wind vector and large-scale soil moisture." }, "relatedTo": { "ob_id": 32013, "uuid": "99251b53c2e84901b4bf6ec6fd78ad51", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.2", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12430, "platform": { "ob_id": 29941, "uuid": "2b126b39dbb64c0681f12b68f2308fee", "short_code": "plat", "title": "SMAP", "abstract": "The Soil Moisture Active-Passive (SMAP) satelliteis a NASA satellite launched in 2015." }, "instrument": { "ob_id": 29938, "uuid": "e050ad22e3b943f9a5f1563a1e6fb82c", "short_code": "instr", "title": "SMAP", "abstract": "The Soil Moisture Active Passive instrument is a microwave radiometer flown on the NASA SMAP satellite." }, "relatedTo": { "ob_id": 32013, "uuid": "99251b53c2e84901b4bf6ec6fd78ad51", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.2", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } } ] }, { "ob_id": 32042, "uuid": "59763d6737c849a083331cc47b69dee8", "short_code": "acq", "title": "Ultrafine and Submicron Particles in the Urban Environment in Thailand: PM10 concentration and composition measurements in Lak Si, Bangkok, Thailand", "abstract": "Ultrafine and Submicron Particles in the Urban Environment in Thailand: PM10 concentration and composition measurements in Lak Si, Bangkok, Thailand", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12431, "platform": { "ob_id": 28095, "uuid": "2d34269b1f1b45c785724a912989be90", "short_code": "plat", "title": "Chulabhorn Research Institute Building, Lak Si", "abstract": "Chulabhorn Research Institute is a biomedical and chemistry research institute in Bangkok, Thailand." }, "instrument": { "ob_id": 28094, "uuid": "95119f0a3b1f4c0bb0846b3dd08055d0", "short_code": "instr", "title": "University of Bristol: Sven Leckel LVS3", "abstract": "Sven Leckel LVS3 is a particle sampler." }, "relatedTo": { "ob_id": 32042, "uuid": "59763d6737c849a083331cc47b69dee8", "short_code": "acq", "title": "Ultrafine and Submicron Particles in the Urban Environment in Thailand: PM10 concentration and composition measurements in Lak Si, Bangkok, Thailand", "abstract": "Ultrafine and Submicron Particles in the Urban Environment in Thailand: PM10 concentration and composition measurements in Lak Si, Bangkok, Thailand" } } ] }, { "ob_id": 32046, "uuid": "8485b88833e84e8f8b05061c161e549b", "short_code": "acq", "title": "Ultrafine and Submicron Particles in the Urban Environment in Thailand: Aerosol concentration and composition size distributions in four locations near Bangkok, Thailand", "abstract": "Ultrafine and Submicron Particles in the Urban Environment in Thailand: Aerosol concentration and composition size distributions in four locations near Bangkok, Thailand", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12432, "platform": { "ob_id": 28095, "uuid": "2d34269b1f1b45c785724a912989be90", "short_code": "plat", "title": "Chulabhorn Research Institute Building, Lak Si", "abstract": "Chulabhorn Research Institute is a biomedical and chemistry research institute in Bangkok, Thailand." }, "instrument": { "ob_id": 32045, "uuid": "41ed782cf88d42a0a5c4bacd5e4f564e", "short_code": "instr", "title": "University of Bristol: Dekati ELPI Classic", "abstract": "SDekati Electrical Low Pressure Impactor, serial number 24413" }, "relatedTo": { "ob_id": 32046, "uuid": "8485b88833e84e8f8b05061c161e549b", "short_code": "acq", "title": "Ultrafine and Submicron Particles in the Urban Environment in Thailand: Aerosol concentration and composition size distributions in four locations near Bangkok, Thailand", "abstract": "Ultrafine and Submicron Particles in the Urban Environment in Thailand: Aerosol concentration and composition size distributions in four locations near Bangkok, Thailand" } } ] }, { "ob_id": 32080, "uuid": "106bed3e19394ca5ace4f89785109cb7", "short_code": "acq", "title": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe", "abstract": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12433, "platform": { "ob_id": 24927, "uuid": "a8aa0f0e0a0745eb900bd41c37592212", "short_code": "plat", "title": "Swedish Maritime Administration Icebreaker Oden", "abstract": "The polar classed Icebreaker Oden (call sign SMLQ) is designed as a combined escort icebreaker and research vessel. She was the first non-nuclear icebreaker at the North Pole in 1991, with a total of seven visits. Between the years 2006-2011 she conducted five successful cruises to Antarctica. In the course of time, Oden has been upgraded and fitted with advanced scientific equipment. It was also deployed during the 2014 Arctic Cloud Summer Expedition (ACSE)." }, "instrument": { "ob_id": 24939, "uuid": "6c0c95b6607e4e7dbad406a34a431fc6", "short_code": "instr", "title": "University of Leeds: Metek USA-100 sonic anemometer", "abstract": "The University of Leeds Metek USA-100 sonic anemometer measures turbulent winds and sonic temperature at 20Hz. 20Hz raw data are available from which average fluxes (e.g. 20 minute average fluxes) can be calculated." }, "relatedTo": { "ob_id": 32080, "uuid": "106bed3e19394ca5ace4f89785109cb7", "short_code": "acq", "title": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe", "abstract": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe" } }, { "ob_id": 12434, "platform": { "ob_id": 24927, "uuid": "a8aa0f0e0a0745eb900bd41c37592212", "short_code": "plat", "title": "Swedish Maritime Administration Icebreaker Oden", "abstract": "The polar classed Icebreaker Oden (call sign SMLQ) is designed as a combined escort icebreaker and research vessel. She was the first non-nuclear icebreaker at the North Pole in 1991, with a total of seven visits. Between the years 2006-2011 she conducted five successful cruises to Antarctica. In the course of time, Oden has been upgraded and fitted with advanced scientific equipment. It was also deployed during the 2014 Arctic Cloud Summer Expedition (ACSE)." }, "instrument": { "ob_id": 32075, "uuid": "95cde815f01a4e648778c92d8b807e03", "short_code": "instr", "title": "Vaisala HMP110 temperature and humidity probe", "abstract": "Vaisala HMP110 temperature and humidity probe" }, "relatedTo": { "ob_id": 32080, "uuid": "106bed3e19394ca5ace4f89785109cb7", "short_code": "acq", "title": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe", "abstract": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe" } }, { "ob_id": 12435, "platform": { "ob_id": 24927, "uuid": "a8aa0f0e0a0745eb900bd41c37592212", "short_code": "plat", "title": "Swedish Maritime Administration Icebreaker Oden", "abstract": "The polar classed Icebreaker Oden (call sign SMLQ) is designed as a combined escort icebreaker and research vessel. She was the first non-nuclear icebreaker at the North Pole in 1991, with a total of seven visits. Between the years 2006-2011 she conducted five successful cruises to Antarctica. In the course of time, Oden has been upgraded and fitted with advanced scientific equipment. It was also deployed during the 2014 Arctic Cloud Summer Expedition (ACSE)." }, "instrument": { "ob_id": 32076, "uuid": "add5d79c4c1049d6bfdcd6c5c7de2e82", "short_code": "instr", "title": "T-type thermocouples", "abstract": "The Type T is a very stable thermocouple and is often used in extremely low temperature applications such as cryogenics or ultra low freezers." }, "relatedTo": { "ob_id": 32080, "uuid": "106bed3e19394ca5ace4f89785109cb7", "short_code": "acq", "title": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe", "abstract": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe" } }, { "ob_id": 12436, "platform": { "ob_id": 24927, "uuid": "a8aa0f0e0a0745eb900bd41c37592212", "short_code": "plat", "title": "Swedish Maritime Administration Icebreaker Oden", "abstract": "The polar classed Icebreaker Oden (call sign SMLQ) is designed as a combined escort icebreaker and research vessel. She was the first non-nuclear icebreaker at the North Pole in 1991, with a total of seven visits. Between the years 2006-2011 she conducted five successful cruises to Antarctica. In the course of time, Oden has been upgraded and fitted with advanced scientific equipment. It was also deployed during the 2014 Arctic Cloud Summer Expedition (ACSE)." }, "instrument": { "ob_id": 32077, "uuid": "b61381027bbb432185707e3b6d20a14d", "short_code": "instr", "title": "NRG Type 40 cupanemometers", "abstract": "NRG Type 40 cupanemometers measures wind speed." }, "relatedTo": { "ob_id": 32080, "uuid": "106bed3e19394ca5ace4f89785109cb7", "short_code": "acq", "title": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe", "abstract": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe" } }, { "ob_id": 12437, "platform": { "ob_id": 24927, "uuid": "a8aa0f0e0a0745eb900bd41c37592212", "short_code": "plat", "title": "Swedish Maritime Administration Icebreaker Oden", "abstract": "The polar classed Icebreaker Oden (call sign SMLQ) is designed as a combined escort icebreaker and research vessel. She was the first non-nuclear icebreaker at the North Pole in 1991, with a total of seven visits. Between the years 2006-2011 she conducted five successful cruises to Antarctica. In the course of time, Oden has been upgraded and fitted with advanced scientific equipment. It was also deployed during the 2014 Arctic Cloud Summer Expedition (ACSE)." }, "instrument": { "ob_id": 32078, "uuid": "e66f3221c2b34cb3ac4e9d09676a02a5", "short_code": "instr", "title": "Kipp & Zonen CMP22 pyranometer", "abstract": "Kipp & Zonen CMP22 pyranometer measures solar irradiance on a planar surface." }, "relatedTo": { "ob_id": 32080, "uuid": "106bed3e19394ca5ace4f89785109cb7", "short_code": "acq", "title": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe", "abstract": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe" } }, { "ob_id": 12438, "platform": { "ob_id": 24927, "uuid": "a8aa0f0e0a0745eb900bd41c37592212", "short_code": "plat", "title": "Swedish Maritime Administration Icebreaker Oden", "abstract": "The polar classed Icebreaker Oden (call sign SMLQ) is designed as a combined escort icebreaker and research vessel. She was the first non-nuclear icebreaker at the North Pole in 1991, with a total of seven visits. Between the years 2006-2011 she conducted five successful cruises to Antarctica. In the course of time, Oden has been upgraded and fitted with advanced scientific equipment. It was also deployed during the 2014 Arctic Cloud Summer Expedition (ACSE)." }, "instrument": { "ob_id": 32079, "uuid": "dda133ffd5f24a20a839450a2059ac4b", "short_code": "instr", "title": "CGR4 pyrgeometer", "abstract": "CGR4 pyrgeometer measures solar radiance." }, "relatedTo": { "ob_id": 32080, "uuid": "106bed3e19394ca5ace4f89785109cb7", "short_code": "acq", "title": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe", "abstract": "Microbiology-Ocean-Cloud Coupling in the High Arctic (MOCCHA): Meteorological data from the measurement station on the ice floe" } } ] }, { "ob_id": 32106, "uuid": "fc88cbb3da4f45f3920996d8ad60c584", "short_code": "acq", "title": "NCAS X-band Radar at Sandwith, Cumbria for RAINE", "abstract": "Scan data from the National Centre for Atmospheric Science Atmospheric Measurement and Observation Facility's mobile X-band radar during the Radar Applications in Northern England (RAIN-E) project.", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12439, "platform": { "ob_id": 32105, "uuid": "969d4fc0933d4a25971cdf3636ba01c7", "short_code": "plat", "title": "Sandwith, Whitehaven, Cumbria", "abstract": "Site of NCAS mobile x-band radar for RAINE project" }, "instrument": { "ob_id": 12250, "uuid": "792da2ff61f647aa8021b4b9c06702a9", "short_code": "instr", "title": "NCAS Atmospheric Measurement Facility's (AMOF) mobile X-band radar 1", "abstract": "The National Centre for Atmospheric Science Atmospheric Measurement Facility's (NCAS AMOF) mobile X-band radar operates in the X-band (frequency = 9.375 GHz, wavelength = 3 cm). It has Doppler and dual-polarisation capability. The radar measures the location and intensity of precipitation, radial winds and polarisation parameters. It works by transmitting pulses of electromagnetic radiation and measuring the amount of energy backscattered to the receiver. The time delay between the transmitted and received pulses enables the range of the object to be determined. In the case of precipitation, the magnitude of the backscattered signal is proportional to the size and number of raindrops. The radar also measures the radial velocity through the Doppler effect. In the absence of precipitation, the radar is sensitive to backscattering from insects, known as clear-air echoes, at close range. These signals provide information on the wind field and the organisation of the boundary-layer e.g. features such as convergence lines can be identified. In addition, the radar has dual-polarisation capability; it simultaneously transmits and receives horizontally- and vertically- polarised waves. Through this technique the radar measures a number of additional variables that provide information on the size and shape of precipitation, identification of non-meteorological echoes, attenuation (a decrease in the signal strength due to the absorption and scattering of the radar signal as it propagates through heavy rain), and alternative methods for calculating rainfall rates. \r\n\r\nThe system has a conventional parabolic antenna of 2.4m diameter and a beamwidth of 1 degree (in the horizontal and vertical), and is operated without a radome. The range resolution is tunable and dependent on the user-selected pulse width (0.5, 1 or 2 micro seconds) and pulse repetition frequency (PRF, 250-2000 Hz). The radar is fully transportable, being mounted on a trailer approved for EU roads that can be towed by a 4x4 vehicle. Signal analysis, data retrievals and data storage are performed by PCs contained within the trailer unit. The radar can be operated via a laptop that connects by wireless, ethernet or 3G to the onboard PCs. The operational software allows the user to set up the radar for deployment and schedule the scanning sequence. The software also provides real-time data visualisation and product generation.\r\n\r\nThe data frequency is dependant on the requirements for the instrument's deployment, but is typically of the order of 10 360-degree scans at various elevations every 5 minutes.\r\n\r\nParameters available in data files from this instrument include: \r\nDOP - degree of polarization; \r\nKDP - specific differential phase shift; \r\nPhiDP - differential phase shift; \r\nRhoHV - co-polar cross correlation coefficient; \r\nSQI - signal quality index or normalized_coherent_power; \r\nV - radial velocity; \r\nW - spectral width; \r\nZDR - differential reflectivity; \r\ndBZ - reflectivity or equivalent reflectivity factor." }, "relatedTo": { "ob_id": 32106, "uuid": "fc88cbb3da4f45f3920996d8ad60c584", "short_code": "acq", "title": "NCAS X-band Radar at Sandwith, Cumbria for RAINE", "abstract": "Scan data from the National Centre for Atmospheric Science Atmospheric Measurement and Observation Facility's mobile X-band radar during the Radar Applications in Northern England (RAIN-E) project." } } ] }, { "ob_id": 32121, "uuid": "dd90db9f07d3463096622565b5389ac4", "short_code": "acq", "title": "APHH: VOC measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: VOC measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12440, "platform": { "ob_id": 30219, "uuid": "07a71f4e62e2468391f492b85905167c", "short_code": "plat", "title": "Indira Gandhi Delhi Technical University for Women (IGDTUW)", "abstract": "Indira Gandhi Delhi Technical University for Women (IGDTUW) which is situated on the periphery of Old Delhi and overlooks a very heavily populated area. As part of the DelhiFlux project the team have constructed a rooftop mast at 4m and a 30 m tall flux tower from which to directly measure pollutant emissions from two contrasting regions of Delhi." }, "instrument": { "ob_id": 71, "uuid": "e83377d7770b4ac3b9ecf8d6eeaf769b", "short_code": "instr", "title": "York: Dual Column Gas Chromatograph-Flame Ionization Detector (DC-GC-FID)", "abstract": "The Dual Channel Gas Chromatograph with Flame Ionisation Detectors is capable of reporting mixing ratios of a wide range of volatile organic compounds in the atmosphere. \r\n\r\nThe output includes mixing ratios of a wide range of volatile organic compounds (VOCs). The data from the instrument are split (across three seperate files: -fid1, -fid2, -fid3) according to compound type. The output for -fid1 is Alkanes.\r\n\r\nThe instrument has variable measurement frequency dependent upon sampling frequency of the Whole Air Sampling (WAS) system.\r\n\r\nSamples of air are dried, and then pre-concentrated on a dual-bed adsorbent trap held at sub-ambient temperature (typically -20°C). Sample volumes of up to one litre of air are acquired and then the trap is resistively heated during desorption within a stream of helium (or hydrogen) and injected into the GC oven for analysis. The eluent is split in approximately equal portions between a Na2SO4 deactivated aluminium oxide (Al2O3) porous layer open tubular (PLOT) column (50 m, 0.53 mm id, Varian Netherlands) for analysis of the less polar NMHCs and a LOWOX columns (10 m, 0.53 mm id, Varian Netherlands) for analysis of the more polar VOCs including monoterpenes and oxygenated species. Analytes elute from the GC columns into two flame ionisation detectors for detection. The GC oven has been programmed for optimal separation of all compounds of interest. \r\n\r\nThere are two near-identical GC instruments for the measurement of Volatile organic compounds. The first is a Perkin Elmer GC with home-built autosampler and flow control box, a home-built preconcentrator and an Ai Qualitek injector. The other is an Agilent GC with a MARKES UNITY2 preconcentrator and CIA Advantage autosampler. \r\n\r\nMeasurement of VOCs in the atmosphere have been used for a wide range of applications including providing information regarding: quantification of emissions; air mass age; and atmospheric processing during transport." }, "relatedTo": { "ob_id": 32121, "uuid": "dd90db9f07d3463096622565b5389ac4", "short_code": "acq", "title": "APHH: VOC measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: VOC measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018" } } ] }, { "ob_id": 32128, "uuid": "22d0f387ba5748c794006d18d94c2f57", "short_code": "acq", "title": "Acquisition Process for Level 1C data from the IASI (Infrared Atmospheric Sounding Interferometer) instrument onboard the MetOp-C satellite.", "abstract": "This acquisition is comprised of the following: INSTRUMENTS: IASI; PLATFORMS: Metop-C", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 32133, "uuid": "3282d841bba742e699cddd6d91327953", "short_code": "mpop", "title": "Mobile Platform Operation for: Metop-C", "abstract": "Mobile Platform Operation related to the: Metop-C" } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12442, "platform": { "ob_id": 32134, "uuid": "db86d823aded474e8c76bd69d092d26b", "short_code": "plat", "title": "Metop-C", "abstract": "Metop-C launched on 7th November 2018, represents the first in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS). Metop-C is Europe's third polar-orbiting meteorological satellite" }, "instrument": { "ob_id": 8300, "uuid": "57fc4dbabdf0434b9584836acac24ffe", "short_code": "instr", "title": "IASI", "abstract": "Data from the IASI instruments on board the Eumetsat EPS MetOp satellite series. The Infrared Atmospheric Sounding Interferometer (IASI) is designed to measure the infrared spectrum emitted by the earth. IASI provides infrared soundings of the temperature profiles in the troposphere and lower stratosphere, moisture profiles in the troposphere, as well as some of the chemical components playing a key role in the climate monitoring, global change and atmospheric chemistry." }, "relatedTo": { "ob_id": 32128, "uuid": "22d0f387ba5748c794006d18d94c2f57", "short_code": "acq", "title": "Acquisition Process for Level 1C data from the IASI (Infrared Atmospheric Sounding Interferometer) instrument onboard the MetOp-C satellite.", "abstract": "This acquisition is comprised of the following: INSTRUMENTS: IASI; PLATFORMS: Metop-C" } } ] }, { "ob_id": 32160, "uuid": "dd5ad889071847649a9fd58ad09fb359", "short_code": "acq", "title": "Iceland Greenland seas Project (IGP): Micro Rain Radar", "abstract": "Iceland Greenland seas Project (IGP): Micro Rain Radar on board Alliance", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12443, "platform": { "ob_id": 26503, "uuid": "e494bef9ef884794a65a341e58205eb2", "short_code": "plat", "title": "Alliance Ship", "abstract": "Alliance is a research ship. The 93 meters, 3,180 t NATO ship NRV ALLIANCE was designed in the mid 80’s as a quiet acoustic research platform. It is capable of operating in all oceans strategically important to NATO nations. ALLIANCE enables scientists and engineers from the Centre and partner nations to conduct a wide range of experiments. The ship is equipped with modern scientific instruments, a sophisticated navigation system, and its deck comprises of a vast array of winches (some fitted and some removable), heavy cranes, a lateral frame and a stern U-frame (including a large 4 drum main tow winch for large arrays). This variety of deck equipment allows a large variety of launch and recovery of scientific and engineering sensors, oceanographic instruments, autonomous vehicles and tethered devices." }, "instrument": { "ob_id": 32158, "uuid": "1d19c577c4e24466ad23eb0d6fad7a00", "short_code": "instr", "title": "University of Bergen: Micro Rain Radar (MRR2)", "abstract": "This is a Micro Rain Radar (MRR2), manufactured by Meteorologische Messtechnik GmbH (Metek) installed onboard the NATO Research Vessel Alliance during the Iceland Greenland Seas Project. \r\nThe MRR2 is a frequency modulated (FM), continuous wave (CW) Radar (Radio Detection and Ranging) that obtains doppler spectral density at each range gate with a time resolution of 10 s. The terminal velocity of the precipitation targets (vT) is the primarily retrieved variable from these doppler spectral density observations. This instrument belongs to and was operated by University of Bergen.\r\n\r\nThe MRR2 transmits at a frequency of 24.230 GHz, which is modulated in a saw tooth pattern. This FM method enables the estimation of the target range in CW scanning mode. The height range configuration during the IGP campaign was set from 75 m to 2325 m at 31 range gates (range bin width is 125m). Due to near field effects, the first two range gates (75 m and 150 m) and due to noise the last range gate (2325 m) are discarded, leaving a range of 225 m to 2250 m. The MRR2 obtains doppler spectral density at each range gate with a time resolution of 10 s.\r\nThe terminal velocity of the precipitation targets (vT) is the primarily retrieved variable from these doppler spectral density observations. Additionally, drop size distribution and the corresponding moments, for example liquid water content (LWC), rain rate (RR) and Radar Reflectivity (Ze) are retrieved with post processing software, provided by Metek. The software only provides yields reasonable results for liquid precipitation, but erroneous vT estimates and insufficient noise removal can be present during snow events. \r\n\r\nMaahn and Kollias (2012) provide a post processing software (IMProToo), that is able to improve the vT estimates, as well as the range gate estimate, by de-aliasing the doppler spectral density. Their software improves the Ze estimates from integrated doppler spectral density. The IGP campaign featured several snow events. Hence, the IMProTool was used in addition to the regular data post processing software by Metek. Both types of data files are included in the IGP dataset." }, "relatedTo": { "ob_id": 32160, "uuid": "dd5ad889071847649a9fd58ad09fb359", "short_code": "acq", "title": "Iceland Greenland seas Project (IGP): Micro Rain Radar", "abstract": "Iceland Greenland seas Project (IGP): Micro Rain Radar on board Alliance" } } ] }, { "ob_id": 32166, "uuid": "ffb464db0cd64ad0984d750d68563bcb", "short_code": "acq", "title": "Aquisition for the ESA Glaciers Climate Change Initiative Inventory of Ice-Marginal Lakes in Greenland project.", "abstract": "Ice marginal lakes were identified using three independent remote sensing methods: 1) multi-temporal backscatter classification from Sentinel-1 synthetic aperture radar imagery; 2) multi-spectral indices classification from Sentinel-2 optical imagery; and 3) sink detection from the ArcticDEM (v3). All data were compiled and filtered in a semi-automated approach, using a modified ice mask to clip the dataset to within 1 km of the ice margin, and then verifying each detected lake manually.\r\n\r\nSentinel 1 Synthetic Aperture Radar (SAR) - The C-band Synthetic Aperture Radar (SAR) flown on the Sentinel 1 series of satellites is an instrument providing high resolution all-weather day and night radar coverage of the Earth's surface. Sentinel 1A was launched on 3rd April 2014 and Sentinel 1B was launched on 25th April 2016. This instrument has four acquisition modes; Stripmap (SM), Interferometric Wide Swath (IW), Extra Wide Swath (EW), and Wave (WV).\r\n\r\nSentinel 2 Multispectral Instrument (MSI) - Data from the Multispectral Instrument (MSI) on the Sentinel 2 series. Sentinel 2A was launched on 23rd June 2015 and Sentinel 2B was launch in March 2017. The instrument provides high-resolution optical imaging data of the Earth's surface.\r\n\r\nArcticDEM - ArcticDEM is an NGA-NSF public-private initiative to automatically produce a high-resolution, high quality, digital surface model (DSM) of the Arctic using optical stereo imagery, high-performance computing, and open source photogrammetry software.", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12444, "platform": { "ob_id": 12319, "uuid": "b6a54b30cf1f45d79e08117ccabeceb6", "short_code": "plat", "title": "Sentinel 1A", "abstract": "Sentinel 1A is the first of the European Space Agency (ESA) Sentinel series. It was launched on 3rd April 2014." }, "instrument": { "ob_id": 12313, "uuid": "0604b6ac4fb24640895c84a25edfd078", "short_code": "instr", "title": "Sentinel 1 Synthetic Aperture Radar (SAR)", "abstract": "The C-band Synthetic Aperture Radar (SAR) flown on the Sentinel 1 series of satellites is an instrument providing high resolution all-weather day and night radar coverage of the Earth's surface.\r\nSentinel 1A was launched on 3rd April 2014 and Sentinel 1B was launched on 25th April 2016. This instrument has four acquisition modes; Stripmap (SM), Interferometric Wide Swath (IW), Extra Wide Swath (EW), and Wave (WV)." }, "relatedTo": { "ob_id": 32166, "uuid": "ffb464db0cd64ad0984d750d68563bcb", "short_code": "acq", "title": "Aquisition for the ESA Glaciers Climate Change Initiative Inventory of Ice-Marginal Lakes in Greenland project.", "abstract": "Ice marginal lakes were identified using three independent remote sensing methods: 1) multi-temporal backscatter classification from Sentinel-1 synthetic aperture radar imagery; 2) multi-spectral indices classification from Sentinel-2 optical imagery; and 3) sink detection from the ArcticDEM (v3). All data were compiled and filtered in a semi-automated approach, using a modified ice mask to clip the dataset to within 1 km of the ice margin, and then verifying each detected lake manually.\r\n\r\nSentinel 1 Synthetic Aperture Radar (SAR) - The C-band Synthetic Aperture Radar (SAR) flown on the Sentinel 1 series of satellites is an instrument providing high resolution all-weather day and night radar coverage of the Earth's surface. Sentinel 1A was launched on 3rd April 2014 and Sentinel 1B was launched on 25th April 2016. This instrument has four acquisition modes; Stripmap (SM), Interferometric Wide Swath (IW), Extra Wide Swath (EW), and Wave (WV).\r\n\r\nSentinel 2 Multispectral Instrument (MSI) - Data from the Multispectral Instrument (MSI) on the Sentinel 2 series. Sentinel 2A was launched on 23rd June 2015 and Sentinel 2B was launch in March 2017. The instrument provides high-resolution optical imaging data of the Earth's surface.\r\n\r\nArcticDEM - ArcticDEM is an NGA-NSF public-private initiative to automatically produce a high-resolution, high quality, digital surface model (DSM) of the Arctic using optical stereo imagery, high-performance computing, and open source photogrammetry software." } }, { "ob_id": 12446, "platform": { "ob_id": 13187, "uuid": "05405d4d4caa47d2889e33b66511fa9b", "short_code": "plat", "title": "Sentinel 2A", "abstract": "Sentinel 2A was launched by the European Space Agency (ESA) to become the second part of the Sentinel series. The satellite was launched on 23rd June 2015." }, "instrument": { "ob_id": 13182, "uuid": "56c6780a9a1d450591dba5b9c848b7c2", "short_code": "instr", "title": "Sentinel 2 Multispectral Instrument (MSI)", "abstract": "Data from the Multispectral Instrument (MSI) on the Sentinel 2 series. Sentinel 2A was launched on 23rd June 2015 and Sentinel 2B was launch in March 2017. The instrument provides high-resolution optical imaging data of the Earth's surface." }, "relatedTo": { "ob_id": 32166, "uuid": "ffb464db0cd64ad0984d750d68563bcb", "short_code": "acq", "title": "Aquisition for the ESA Glaciers Climate Change Initiative Inventory of Ice-Marginal Lakes in Greenland project.", "abstract": "Ice marginal lakes were identified using three independent remote sensing methods: 1) multi-temporal backscatter classification from Sentinel-1 synthetic aperture radar imagery; 2) multi-spectral indices classification from Sentinel-2 optical imagery; and 3) sink detection from the ArcticDEM (v3). All data were compiled and filtered in a semi-automated approach, using a modified ice mask to clip the dataset to within 1 km of the ice margin, and then verifying each detected lake manually.\r\n\r\nSentinel 1 Synthetic Aperture Radar (SAR) - The C-band Synthetic Aperture Radar (SAR) flown on the Sentinel 1 series of satellites is an instrument providing high resolution all-weather day and night radar coverage of the Earth's surface. Sentinel 1A was launched on 3rd April 2014 and Sentinel 1B was launched on 25th April 2016. This instrument has four acquisition modes; Stripmap (SM), Interferometric Wide Swath (IW), Extra Wide Swath (EW), and Wave (WV).\r\n\r\nSentinel 2 Multispectral Instrument (MSI) - Data from the Multispectral Instrument (MSI) on the Sentinel 2 series. Sentinel 2A was launched on 23rd June 2015 and Sentinel 2B was launch in March 2017. The instrument provides high-resolution optical imaging data of the Earth's surface.\r\n\r\nArcticDEM - ArcticDEM is an NGA-NSF public-private initiative to automatically produce a high-resolution, high quality, digital surface model (DSM) of the Arctic using optical stereo imagery, high-performance computing, and open source photogrammetry software." } }, { "ob_id": 12447, "platform": { "ob_id": 25277, "uuid": "0bbb6de9c89b403aba5a2aacf53ec19e", "short_code": "plat", "title": "Sentinel 2B", "abstract": "Sentinel 2B was launched by the European Space Agency (ESA) to become the second part of the Sentinel series alongside Sentinel 2A. The satellite was launched on 7th March 2016." }, "instrument": { "ob_id": 13182, "uuid": "56c6780a9a1d450591dba5b9c848b7c2", "short_code": "instr", "title": "Sentinel 2 Multispectral Instrument (MSI)", "abstract": "Data from the Multispectral Instrument (MSI) on the Sentinel 2 series. Sentinel 2A was launched on 23rd June 2015 and Sentinel 2B was launch in March 2017. The instrument provides high-resolution optical imaging data of the Earth's surface." }, "relatedTo": { "ob_id": 32166, "uuid": "ffb464db0cd64ad0984d750d68563bcb", "short_code": "acq", "title": "Aquisition for the ESA Glaciers Climate Change Initiative Inventory of Ice-Marginal Lakes in Greenland project.", "abstract": "Ice marginal lakes were identified using three independent remote sensing methods: 1) multi-temporal backscatter classification from Sentinel-1 synthetic aperture radar imagery; 2) multi-spectral indices classification from Sentinel-2 optical imagery; and 3) sink detection from the ArcticDEM (v3). All data were compiled and filtered in a semi-automated approach, using a modified ice mask to clip the dataset to within 1 km of the ice margin, and then verifying each detected lake manually.\r\n\r\nSentinel 1 Synthetic Aperture Radar (SAR) - The C-band Synthetic Aperture Radar (SAR) flown on the Sentinel 1 series of satellites is an instrument providing high resolution all-weather day and night radar coverage of the Earth's surface. Sentinel 1A was launched on 3rd April 2014 and Sentinel 1B was launched on 25th April 2016. This instrument has four acquisition modes; Stripmap (SM), Interferometric Wide Swath (IW), Extra Wide Swath (EW), and Wave (WV).\r\n\r\nSentinel 2 Multispectral Instrument (MSI) - Data from the Multispectral Instrument (MSI) on the Sentinel 2 series. Sentinel 2A was launched on 23rd June 2015 and Sentinel 2B was launch in March 2017. The instrument provides high-resolution optical imaging data of the Earth's surface.\r\n\r\nArcticDEM - ArcticDEM is an NGA-NSF public-private initiative to automatically produce a high-resolution, high quality, digital surface model (DSM) of the Arctic using optical stereo imagery, high-performance computing, and open source photogrammetry software." } }, { "ob_id": 12445, "platform": { "ob_id": 20017, "uuid": "c68fe345e19a47b0a200941896f8aace", "short_code": "plat", "title": "Sentinel 1B", "abstract": "Sentinel 1B is the first of the European Space Agency (ESA) Sentinel series. It was launched on 25th April 2016." }, "instrument": { "ob_id": 12313, "uuid": "0604b6ac4fb24640895c84a25edfd078", "short_code": "instr", "title": "Sentinel 1 Synthetic Aperture Radar (SAR)", "abstract": "The C-band Synthetic Aperture Radar (SAR) flown on the Sentinel 1 series of satellites is an instrument providing high resolution all-weather day and night radar coverage of the Earth's surface.\r\nSentinel 1A was launched on 3rd April 2014 and Sentinel 1B was launched on 25th April 2016. This instrument has four acquisition modes; Stripmap (SM), Interferometric Wide Swath (IW), Extra Wide Swath (EW), and Wave (WV)." }, "relatedTo": { "ob_id": 32166, "uuid": "ffb464db0cd64ad0984d750d68563bcb", "short_code": "acq", "title": "Aquisition for the ESA Glaciers Climate Change Initiative Inventory of Ice-Marginal Lakes in Greenland project.", "abstract": "Ice marginal lakes were identified using three independent remote sensing methods: 1) multi-temporal backscatter classification from Sentinel-1 synthetic aperture radar imagery; 2) multi-spectral indices classification from Sentinel-2 optical imagery; and 3) sink detection from the ArcticDEM (v3). All data were compiled and filtered in a semi-automated approach, using a modified ice mask to clip the dataset to within 1 km of the ice margin, and then verifying each detected lake manually.\r\n\r\nSentinel 1 Synthetic Aperture Radar (SAR) - The C-band Synthetic Aperture Radar (SAR) flown on the Sentinel 1 series of satellites is an instrument providing high resolution all-weather day and night radar coverage of the Earth's surface. Sentinel 1A was launched on 3rd April 2014 and Sentinel 1B was launched on 25th April 2016. This instrument has four acquisition modes; Stripmap (SM), Interferometric Wide Swath (IW), Extra Wide Swath (EW), and Wave (WV).\r\n\r\nSentinel 2 Multispectral Instrument (MSI) - Data from the Multispectral Instrument (MSI) on the Sentinel 2 series. Sentinel 2A was launched on 23rd June 2015 and Sentinel 2B was launch in March 2017. The instrument provides high-resolution optical imaging data of the Earth's surface.\r\n\r\nArcticDEM - ArcticDEM is an NGA-NSF public-private initiative to automatically produce a high-resolution, high quality, digital surface model (DSM) of the Arctic using optical stereo imagery, high-performance computing, and open source photogrammetry software." } } ] }, { "ob_id": 32172, "uuid": "eecccb3dca4e40acb6c2c23357b19875", "short_code": "acq", "title": "Filter Packs and Cascade Impactors for the collection of sample on the island of Hawaii 2018-2019", "abstract": "Filter packs: Filter pack samplers were used to collect simultaneous samples of gas and bulk PM. The filter packs comprised one particle filter followed by 2-4 base-treated gas filters in an all-Teflon cartridge. Gas filters (Whatman Quantitative Filter Papers, Ashless, Grade 41, 55mm diameter) were pre-soaked with a 0.1M K2CO3 (+ glycerol) and dried approximately one week before use in the field. This base treatment of the gas filters capture acidic gases (e.g., SO2, HF and HCl). For some samples, the last gas filter in the filter pack contained >10% of the total captured gas concentration – this is evidence that the gas filters had become saturated; these gas samples are identified in the data file as 'saturated'. The particle filter collects bulk (non size-resolved) PM. The particle filter used was Whatman PTFE 47 mm diameter, pore size 0.8 µm. The filters were pre-washed with UPA grade nitric acid before use on the 2019 campaign. The filters were not pre-washed before the 2018 campaign. Field and lab filter blanks were used to quantify the level of contamination due to the absence of acid wash. The contamination was found to be negligible in most samples due to the high sampled concentrations in the eruption-affected atmosphere in 2018. Airflow through the filter pack was generated using an external 12 V pump (Charles Austin Capex) running at ~20 l min-1. The flow rate was measured at the start and end of each sampling period. The uncertainty introduced by variations in the flow rate, and by the accuracy of the flow meter are 10%.\r\n\r\nCascade impactors: Cascade impactors size and collect particles through inertial impaction onto a series of stages. A filter is placed onto each stage to collect the PM. We used a 5-stage SKC Inc. Sioutas impactor with Whatman and Zefluor PTFE filters (25 mm diameter on stages 1-4 and 37 mm diameter on stage 5, 0.2 µm pore size). Filters were acid-washed following the same procedure as described for filter packs. The Sioutas impactor resolves 5 size fractions between >2.5 µm and >0.25 µm at a flow rate of 9 l min-1. Airflow is created by an external pump with inbuilt battery (SKC Leland Legacy). The pumps had been calibrated prior to both campaigns by the manufacturer, with reported accuracy in the flow rate of 5%.", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12448, "platform": { "ob_id": 32175, "uuid": "f0ae2fb566524fa3a2d9aee250d9a3a3", "short_code": "plat", "title": "Kilauea volcano sample sites Hawaii", "abstract": "Samples for this experiment were taken for the Kilauea volcano on the island of Hawai'i\r\n\r\nSamples were collected in several locations on the Island of Hawai'i, Hawaii, USA. Time-series samples were collected at Leilani Estates, Volcano village, Pahala, Ocean View, Kailua-Kona and Mauna Loa Observatory in 2018 and 2019. \r\n\r\nPoint-source samples were collected at the main erupting vent 'Fissure 8' (2018, repeated in its vicinity post-eruption in 2019); lava ocean entry point (2018, repeated in its vicinity post-eruption in 2019). When: 18-31 July 2018; 25 June - 3 July 2019" }, "instrument": { "ob_id": 32173, "uuid": "d851991f88f84a618d88fc5b993f89e6", "short_code": "instr", "title": "Filter Pack Samplers", "abstract": "Filter packs: Filter pack samplers were used to collect simultaneous samples of gas and bulk PM. The filter packs comprised one particle filter followed by 2-4 base-treated gas filters in an all-Teflon cartridge. Gas filters (Whatman Quantitative Filter Papers, Ashless, Grade 41, 55mm diameter) were pre-soaked with a 0.1M K2CO3 (+ glycerol) and dried approximately one week before use in the field. This base treatment of the gas filters capture acidic gases (e.g., SO2, HF and HCl). For some samples, the last gas filter in the filter pack contained >10% of the total captured gas concentration – this is evidence that the gas filters had become saturated; these gas samples are identified in the data file as 'saturated'. The particle filter collects bulk (non size-resolved) PM. The particle filter used was Whatman PTFE 47 mm diameter, pore size 0.8 µm. The filters were pre-washed with UPA grade nitric acid before use on the 2019 campaign. The filters were not pre-washed before the 2018 campaign. Field and lab filter blanks were used to quantify the level of contamination due to the absence of acid wash. The contamination was found to be negligible in most samples due to the high sampled concentrations in the eruption-affected atmosphere in 2018. Airflow through the filter pack was generated using an external 12 V pump (Charles Austin Capex) running at ~20 l min-1. The flow rate was measured at the start and end of each sampling period. The uncertainty introduced by variations in the flow rate, and by the accuracy of the flow meter are 10%." }, "relatedTo": { "ob_id": 32172, "uuid": "eecccb3dca4e40acb6c2c23357b19875", "short_code": "acq", "title": "Filter Packs and Cascade Impactors for the collection of sample on the island of Hawaii 2018-2019", "abstract": "Filter packs: Filter pack samplers were used to collect simultaneous samples of gas and bulk PM. The filter packs comprised one particle filter followed by 2-4 base-treated gas filters in an all-Teflon cartridge. Gas filters (Whatman Quantitative Filter Papers, Ashless, Grade 41, 55mm diameter) were pre-soaked with a 0.1M K2CO3 (+ glycerol) and dried approximately one week before use in the field. This base treatment of the gas filters capture acidic gases (e.g., SO2, HF and HCl). For some samples, the last gas filter in the filter pack contained >10% of the total captured gas concentration – this is evidence that the gas filters had become saturated; these gas samples are identified in the data file as 'saturated'. The particle filter collects bulk (non size-resolved) PM. The particle filter used was Whatman PTFE 47 mm diameter, pore size 0.8 µm. The filters were pre-washed with UPA grade nitric acid before use on the 2019 campaign. The filters were not pre-washed before the 2018 campaign. Field and lab filter blanks were used to quantify the level of contamination due to the absence of acid wash. The contamination was found to be negligible in most samples due to the high sampled concentrations in the eruption-affected atmosphere in 2018. Airflow through the filter pack was generated using an external 12 V pump (Charles Austin Capex) running at ~20 l min-1. The flow rate was measured at the start and end of each sampling period. The uncertainty introduced by variations in the flow rate, and by the accuracy of the flow meter are 10%.\r\n\r\nCascade impactors: Cascade impactors size and collect particles through inertial impaction onto a series of stages. A filter is placed onto each stage to collect the PM. We used a 5-stage SKC Inc. Sioutas impactor with Whatman and Zefluor PTFE filters (25 mm diameter on stages 1-4 and 37 mm diameter on stage 5, 0.2 µm pore size). Filters were acid-washed following the same procedure as described for filter packs. The Sioutas impactor resolves 5 size fractions between >2.5 µm and >0.25 µm at a flow rate of 9 l min-1. Airflow is created by an external pump with inbuilt battery (SKC Leland Legacy). The pumps had been calibrated prior to both campaigns by the manufacturer, with reported accuracy in the flow rate of 5%." } }, { "ob_id": 12449, "platform": { "ob_id": 32175, "uuid": "f0ae2fb566524fa3a2d9aee250d9a3a3", "short_code": "plat", "title": "Kilauea volcano sample sites Hawaii", "abstract": "Samples for this experiment were taken for the Kilauea volcano on the island of Hawai'i\r\n\r\nSamples were collected in several locations on the Island of Hawai'i, Hawaii, USA. Time-series samples were collected at Leilani Estates, Volcano village, Pahala, Ocean View, Kailua-Kona and Mauna Loa Observatory in 2018 and 2019. \r\n\r\nPoint-source samples were collected at the main erupting vent 'Fissure 8' (2018, repeated in its vicinity post-eruption in 2019); lava ocean entry point (2018, repeated in its vicinity post-eruption in 2019). When: 18-31 July 2018; 25 June - 3 July 2019" }, "instrument": { "ob_id": 32174, "uuid": "a08cce2f20694595a78b5eec707fde0b", "short_code": "instr", "title": "Sioutas Impactor", "abstract": "Cascade impactors: Cascade impactors size and collect particles through inertial impaction onto a series of stages. A filter is placed onto each stage to collect the PM. We used a 5-stage SKC Inc. Sioutas impactor with Whatman and Zefluor PTFE filters (25 mm diameter on stages 1-4 and 37 mm diameter on stage 5, 0.2 µm pore size). Filters were acid-washed following the same procedure as described for filter packs. The Sioutas impactor resolves 5 size fractions between >2.5 µm and >0.25 µm at a flow rate of 9 l min-1. Airflow is created by an external pump with inbuilt battery (SKC Leland Legacy). The pumps had been calibrated prior to both campaigns by the manufacturer, with reported accuracy in the flow rate of 5%.." }, "relatedTo": { "ob_id": 32172, "uuid": "eecccb3dca4e40acb6c2c23357b19875", "short_code": "acq", "title": "Filter Packs and Cascade Impactors for the collection of sample on the island of Hawaii 2018-2019", "abstract": "Filter packs: Filter pack samplers were used to collect simultaneous samples of gas and bulk PM. The filter packs comprised one particle filter followed by 2-4 base-treated gas filters in an all-Teflon cartridge. Gas filters (Whatman Quantitative Filter Papers, Ashless, Grade 41, 55mm diameter) were pre-soaked with a 0.1M K2CO3 (+ glycerol) and dried approximately one week before use in the field. This base treatment of the gas filters capture acidic gases (e.g., SO2, HF and HCl). For some samples, the last gas filter in the filter pack contained >10% of the total captured gas concentration – this is evidence that the gas filters had become saturated; these gas samples are identified in the data file as 'saturated'. The particle filter collects bulk (non size-resolved) PM. The particle filter used was Whatman PTFE 47 mm diameter, pore size 0.8 µm. The filters were pre-washed with UPA grade nitric acid before use on the 2019 campaign. The filters were not pre-washed before the 2018 campaign. Field and lab filter blanks were used to quantify the level of contamination due to the absence of acid wash. The contamination was found to be negligible in most samples due to the high sampled concentrations in the eruption-affected atmosphere in 2018. Airflow through the filter pack was generated using an external 12 V pump (Charles Austin Capex) running at ~20 l min-1. The flow rate was measured at the start and end of each sampling period. The uncertainty introduced by variations in the flow rate, and by the accuracy of the flow meter are 10%.\r\n\r\nCascade impactors: Cascade impactors size and collect particles through inertial impaction onto a series of stages. A filter is placed onto each stage to collect the PM. We used a 5-stage SKC Inc. Sioutas impactor with Whatman and Zefluor PTFE filters (25 mm diameter on stages 1-4 and 37 mm diameter on stage 5, 0.2 µm pore size). Filters were acid-washed following the same procedure as described for filter packs. The Sioutas impactor resolves 5 size fractions between >2.5 µm and >0.25 µm at a flow rate of 9 l min-1. Airflow is created by an external pump with inbuilt battery (SKC Leland Legacy). The pumps had been calibrated prior to both campaigns by the manufacturer, with reported accuracy in the flow rate of 5%." } } ] }, { "ob_id": 32180, "uuid": "d01eee4308ac4c1eacd841cd82fd778c", "short_code": "acq", "title": "Methane Observations and Yearly Assessments (MOYA): lower troposphere greenhouse gas data taken over Pantanal, Mato Grosso do Sul, Brazil", "abstract": "Methane Observations and Yearly Assessments (MOYA): lower troposphere greenhouse gas data taken over Pantanal, Mato Grosso do Sul, Brazil", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12450, "platform": { "ob_id": 32177, "uuid": "74be10c3e82d4f058a0107e0c04c5637", "short_code": "plat", "title": "Unknown research aircraft", "abstract": "Unknown research aircraft" }, "instrument": { "ob_id": 25435, "uuid": "53ea242da0ef4f89b1692426792a8d36", "short_code": "instr", "title": "CO2 LICOR Analyzer unknown specification", "abstract": "CO2 LICOR Analyzer 7000 used to measure CO2 in the Amazonica project.\r\n\r\nCO2 is a strong absorber in the near infrared wavelength domain of electromagnetic radiation. The instrument measures the intensity of an infrared electromagnetic wave which passed through the air sample to be analysed. The intensity is then being compared with intensities measured for different calibration gas samples for which the dry air CO2 mixing ratio is known." }, "relatedTo": { "ob_id": 32180, "uuid": "d01eee4308ac4c1eacd841cd82fd778c", "short_code": "acq", "title": "Methane Observations and Yearly Assessments (MOYA): lower troposphere greenhouse gas data taken over Pantanal, Mato Grosso do Sul, Brazil", "abstract": "Methane Observations and Yearly Assessments (MOYA): lower troposphere greenhouse gas data taken over Pantanal, Mato Grosso do Sul, Brazil" } }, { "ob_id": 12451, "platform": { "ob_id": 32177, "uuid": "74be10c3e82d4f058a0107e0c04c5637", "short_code": "plat", "title": "Unknown research aircraft", "abstract": "Unknown research aircraft" }, "instrument": { "ob_id": 32178, "uuid": "d4b3700848224602a42cc0a42582c2e2", "short_code": "instr", "title": "Peak Laboratories model P1", "abstract": "Peak Laboratories model P1" }, "relatedTo": { "ob_id": 32180, "uuid": "d01eee4308ac4c1eacd841cd82fd778c", "short_code": "acq", "title": "Methane Observations and Yearly Assessments (MOYA): lower troposphere greenhouse gas data taken over Pantanal, Mato Grosso do Sul, Brazil", "abstract": "Methane Observations and Yearly Assessments (MOYA): lower troposphere greenhouse gas data taken over Pantanal, Mato Grosso do Sul, Brazil" } }, { "ob_id": 12452, "platform": { "ob_id": 32177, "uuid": "74be10c3e82d4f058a0107e0c04c5637", "short_code": "plat", "title": "Unknown research aircraft", "abstract": "Unknown research aircraft" }, "instrument": { "ob_id": 32179, "uuid": "3e8aaff0aa7d43f8ba2f8e95599e3516", "short_code": "instr", "title": "Gas chromatgraph HP model 6890 series Plus", "abstract": "Gas chromatgraph HP model 6890 series Plus" }, "relatedTo": { "ob_id": 32180, "uuid": "d01eee4308ac4c1eacd841cd82fd778c", "short_code": "acq", "title": "Methane Observations and Yearly Assessments (MOYA): lower troposphere greenhouse gas data taken over Pantanal, Mato Grosso do Sul, Brazil", "abstract": "Methane Observations and Yearly Assessments (MOYA): lower troposphere greenhouse gas data taken over Pantanal, Mato Grosso do Sul, Brazil" } } ] }, { "ob_id": 32184, "uuid": "101346bcd1db4ecf8ffa1084deb81496", "short_code": "acq", "title": "Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Llanos de Moxos, Bolivia,", "abstract": "Methane Observations and Yearly Assessments (MOYA): Isotopic d13C methane measurements taken from Llanos de Moxos, Bolivia,", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [ 13716 ], "instrumentplatformpair_set": [] }, { "ob_id": 32190, "uuid": "018788dade004627b0cb2fdc853e5572", "short_code": "acq", "title": "APHH: Photolysis rate measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Photolysis rate measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12453, "platform": { "ob_id": 30219, "uuid": "07a71f4e62e2468391f492b85905167c", "short_code": "plat", "title": "Indira Gandhi Delhi Technical University for Women (IGDTUW)", "abstract": "Indira Gandhi Delhi Technical University for Women (IGDTUW) which is situated on the periphery of Old Delhi and overlooks a very heavily populated area. As part of the DelhiFlux project the team have constructed a rooftop mast at 4m and a 30 m tall flux tower from which to directly measure pollutant emissions from two contrasting regions of Delhi." }, "instrument": { "ob_id": 32189, "uuid": "8b48bee820bc4bef930830c71990a822", "short_code": "instr", "title": "University of York: Spectral Radiometer", "abstract": "The spectral radiometer provides a direct measurement of solar actinic UV flux and determination of photolysis frequencies. The actinic flux is measured between 280 - 650 nm (<1 nm resolution) using a spectral radiometer (Ocean Optics QE5000) attached to a quartz receiver optic (Metcon). Photolysis rates are derived from the product of absorption cross-section of the precursor molecule, the quantum yield of the photo-product and the actinic flux density (cm-2s-1nm-1)." }, "relatedTo": { "ob_id": 32190, "uuid": "018788dade004627b0cb2fdc853e5572", "short_code": "acq", "title": "APHH: Photolysis rate measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Photolysis rate measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018" } } ] }, { "ob_id": 32209, "uuid": "c7f5bf15ef53420e80bc47a833bb0b7d", "short_code": "acq", "title": "APHH: Aethalometer measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Aethalometer measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12454, "platform": { "ob_id": 30219, "uuid": "07a71f4e62e2468391f492b85905167c", "short_code": "plat", "title": "Indira Gandhi Delhi Technical University for Women (IGDTUW)", "abstract": "Indira Gandhi Delhi Technical University for Women (IGDTUW) which is situated on the periphery of Old Delhi and overlooks a very heavily populated area. As part of the DelhiFlux project the team have constructed a rooftop mast at 4m and a 30 m tall flux tower from which to directly measure pollutant emissions from two contrasting regions of Delhi." }, "instrument": { "ob_id": 11751, "uuid": "534ceb3b8838e05472867fc5a3c2a4a4", "short_code": "instr", "title": "Aethalometer", "abstract": "Instrument.abstract: DETAILS NEEDED" }, "relatedTo": { "ob_id": 32209, "uuid": "c7f5bf15ef53420e80bc47a833bb0b7d", "short_code": "acq", "title": "APHH: Aethalometer measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Aethalometer measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018" } } ] }, { "ob_id": 32212, "uuid": "cb3b6711b71742d3a4079ce44a42fdc9", "short_code": "acq", "title": "APHH: Multi Angle Absorption Photometer (MAAP) measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Multi Angle Absorption Photometer (MAAP) measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12455, "platform": { "ob_id": 30219, "uuid": "07a71f4e62e2468391f492b85905167c", "short_code": "plat", "title": "Indira Gandhi Delhi Technical University for Women (IGDTUW)", "abstract": "Indira Gandhi Delhi Technical University for Women (IGDTUW) which is situated on the periphery of Old Delhi and overlooks a very heavily populated area. As part of the DelhiFlux project the team have constructed a rooftop mast at 4m and a 30 m tall flux tower from which to directly measure pollutant emissions from two contrasting regions of Delhi." }, "instrument": { "ob_id": 111, "uuid": "8bf343f7fff8442dab853c3310ba7a63", "short_code": "instr", "title": "University of Manchester Multi-Angle Absorption Photometer (MAAP)", "abstract": "The University of Manchester MAAP (Multi-Angle Absorption Photometer) instrument was specifically developed to reduce the uncertainties in black carbon measurements caused by aerosol scattering." }, "relatedTo": { "ob_id": 32212, "uuid": "cb3b6711b71742d3a4079ce44a42fdc9", "short_code": "acq", "title": "APHH: Multi Angle Absorption Photometer (MAAP) measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Multi Angle Absorption Photometer (MAAP) measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018" } } ] }, { "ob_id": 32216, "uuid": "aa260436749a4202833bd89bf2716cd2", "short_code": "acq", "title": "APHH: Compact Time of Flight Aerosol Mass Spectrometer measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site and India Meteorological Department (IMD) during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Compact Time of Flight Aerosol Mass Spectrometer measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site and India Meteorological Department (IMD) during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12456, "platform": { "ob_id": 30219, "uuid": "07a71f4e62e2468391f492b85905167c", "short_code": "plat", "title": "Indira Gandhi Delhi Technical University for Women (IGDTUW)", "abstract": "Indira Gandhi Delhi Technical University for Women (IGDTUW) which is situated on the periphery of Old Delhi and overlooks a very heavily populated area. As part of the DelhiFlux project the team have constructed a rooftop mast at 4m and a 30 m tall flux tower from which to directly measure pollutant emissions from two contrasting regions of Delhi." }, "instrument": { "ob_id": 11784, "uuid": "04b82d8d064508efb426d828f5b48518", "short_code": "instr", "title": "Compact Time of Flight Aerosol Mass Spectrometer", "abstract": "Compact Time of Flight Aerosol Mass Spectrometer. cToF-AMS. Manchester." }, "relatedTo": { "ob_id": 32216, "uuid": "aa260436749a4202833bd89bf2716cd2", "short_code": "acq", "title": "APHH: Compact Time of Flight Aerosol Mass Spectrometer measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site and India Meteorological Department (IMD) during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Compact Time of Flight Aerosol Mass Spectrometer measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site and India Meteorological Department (IMD) during the pre and post monsoon periods for the DelhiFlux field campaign 2018" } }, { "ob_id": 12457, "platform": { "ob_id": 32215, "uuid": "8ef0d9f4137c4ef3888b750fcc516e42", "short_code": "plat", "title": "India Meteorological Department (IMD)", "abstract": "India Meteorological Department (IMD), Lodhi Road" }, "instrument": { "ob_id": 11784, "uuid": "04b82d8d064508efb426d828f5b48518", "short_code": "instr", "title": "Compact Time of Flight Aerosol Mass Spectrometer", "abstract": "Compact Time of Flight Aerosol Mass Spectrometer. cToF-AMS. Manchester." }, "relatedTo": { "ob_id": 32216, "uuid": "aa260436749a4202833bd89bf2716cd2", "short_code": "acq", "title": "APHH: Compact Time of Flight Aerosol Mass Spectrometer measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site and India Meteorological Department (IMD) during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Compact Time of Flight Aerosol Mass Spectrometer measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site and India Meteorological Department (IMD) during the pre and post monsoon periods for the DelhiFlux field campaign 2018" } } ] }, { "ob_id": 32219, "uuid": "c9e0b3a3434c4a72a490336425a54e28", "short_code": "acq", "title": "Acquisition Process for: Data from the photographic camera the Dornier Do228-101 D-CALM Aircraft during Flight 04/27 over Dorchester", "abstract": "This acquisition is comprised of the following: INSTRUMENTS: ); PLATFORMS: Dornier Do228-101 D-CALM;", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 6410, "uuid": "eb9f0ae42c1c4d87b2bd72543b1be671", "short_code": "mpop", "title": "Mobile Platform Operation for: Dornier Do228-101 D-CALM", "abstract": "Mobile Platform Operation related to the: Dornier Do228-101 D-CALM" } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12458, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 8608, "uuid": "b253208e4d394fb5803379bd0f39dec7", "short_code": "instr", "title": "ARSF WILD-RC10 Analogue Photographic camera", "abstract": "Airborne analogue photographic camera used by the NERC ARSF 199? - 2006. Negatives of frames obtained using this instrument have now been scanned and are available online in JPEG2000 format." }, "relatedTo": { "ob_id": 32219, "uuid": "c9e0b3a3434c4a72a490336425a54e28", "short_code": "acq", "title": "Acquisition Process for: Data from the photographic camera the Dornier Do228-101 D-CALM Aircraft during Flight 04/27 over Dorchester", "abstract": "This acquisition is comprised of the following: INSTRUMENTS: ); PLATFORMS: Dornier Do228-101 D-CALM;" } } ] }, { "ob_id": 32222, "uuid": "0e4160eb57a648178b1b1884610b1893", "short_code": "acq", "title": "APHH: Single Particle Soot Photometer (SP2) measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Single Particle Soot Photometer (SP2) measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12460, "platform": { "ob_id": 30219, "uuid": "07a71f4e62e2468391f492b85905167c", "short_code": "plat", "title": "Indira Gandhi Delhi Technical University for Women (IGDTUW)", "abstract": "Indira Gandhi Delhi Technical University for Women (IGDTUW) which is situated on the periphery of Old Delhi and overlooks a very heavily populated area. As part of the DelhiFlux project the team have constructed a rooftop mast at 4m and a 30 m tall flux tower from which to directly measure pollutant emissions from two contrasting regions of Delhi." }, "instrument": { "ob_id": 11230, "uuid": "4475880cd0f2432fa88d2cbe1e03a791", "short_code": "instr", "title": "Manchester: Single Particle Soot Photometer (SP2)", "abstract": "The Single Particle Soot Photometer (SP2) is manufactured by Droplet Measurement Technologies (DMT). It measures the soot (also known as black carbon) content of individual airborne particles, known as aerosols. \r\n\r\nThe SP2 is a laser-based instrument, which detects black carbon particles by heating them to their point of 'incandescence'. This results in the emission of radiation that can be measured and related to the mass of black carbon. \r\n\r\nThe instrument can be operated in a range of environments (lab, ground-based, aircraft) and its high sensitivity and fast response makes it ideal for a number of atmospheric science applications. The measurement frequency of this instrument is 1Hz. \r\n\r\nThe outputs include: black carbon mass, number and size; as well as information relating to the mixing state of black carbon-containing particles. Number and volume concentration of scattering particles; as well as their optical size are also included. \r\n\r\nBlack carbon is an important component of atmospheric aerosol and is a strong absorber of solar radiation. It is a product of incomplete combustion activities and the major sources include vehicle engines, burning of domestic fuels for heating/cooking and forest/agricultural fires. Human activities have increased the amount of black carbon in the atmosphere, which leads to a warming of the Earth's temperature.\r\n\r\nThis instrument is regularly used on the FAAM BAe 146 aircraft." }, "relatedTo": { "ob_id": 32222, "uuid": "0e4160eb57a648178b1b1884610b1893", "short_code": "acq", "title": "APHH: Single Particle Soot Photometer (SP2) measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018", "abstract": "APHH: Single Particle Soot Photometer (SP2) measurements made at the Indira Gandhi Delhi Technical University for Women (IGDTUW) site during the pre and post monsoon periods for the DelhiFlux field campaign 2018" } } ] }, { "ob_id": 32227, "uuid": "c58157eefd194b0c993d2dc767e6e846", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.3", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments.", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 27137, "uuid": "f6550c6efe0c4a9baaf3c5d07627b2ed", "short_code": "mpop", "title": "GCOM-W satellite orbit details", "abstract": "The GCOM-W (Global Change Observation Mission for Water) is a JAXA satellite in a sunsynchronous orbit with a 13.30 ascending equator crossing time." }, { "ob_id": 27138, "uuid": "44f2493522254d2696575ce3acb6146c", "short_code": "mpop", "title": "TRMM satellite orbit details", "abstract": "The TRMM (Tropical Rainfall Measuring Mission) is a NASA, JAXA satellite mission. It is in a drifting orbit with an inclination of 35 degrees and altitude of 402 km." }, { "ob_id": 2631, "uuid": "4647e36325d544eca3db5d8795c216c6", "short_code": "mpop", "title": "Mobile Platform Operation for: Defense Meteorological Satellite Program (DMSP) Satellites", "abstract": "Mobile Platform Operation related to the: Defense Meteorological Satellite Program (DMSP) Satellites" }, { "ob_id": 460, "uuid": "bea2c6443d2f4f81a2701f09cb4e6f5c", "short_code": "mpop", "title": "Mobile Platform Operation for: NIMBUS 7 Satellite", "abstract": "Mobile Platform Operation related to the: NIMBUS 7 Satellite" }, { "ob_id": 10907, "uuid": "1be652a219874193976dff38a64fc180", "short_code": "mpop", "title": "Aqua Satellite orbit details", "abstract": "NASA's AQUA (EOS-PM1) is a sun-synchronous, polar orbiting satellite in an afternoon orbit, with equator crossing times of approximately 13:30 and 01:30. It forms part of the A-train, a collection of satellites orbiting close together along the same orbital track" }, { "ob_id": 27132, "uuid": "6c74884699f541ff8a1edb33933ddada", "short_code": "mpop", "title": "Coriolis Satellite Orbit Details", "abstract": "The Coriolis Satellite is flown by NASA and the US Department of Defence and is in a Sunsynchronous orbit with an 06.10 descending equator crossing time." }, { "ob_id": 27133, "uuid": "c15fb49dfbf24bdc81acb5ae16df1b1d", "short_code": "mpop", "title": "SMOS satellite orbit details", "abstract": "The SMOS satellite is operated by ESA and is in a sunscynchronous orbit with a 06:00 ascending equator crossing time." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12461, "platform": { "ob_id": 458, "uuid": "b6d87ac1455348cd97a4386b38995dbb", "short_code": "plat", "title": "NIMBUS 7 Satellite", "abstract": "The NASA Nimbus 7 research-and-development polar-orbiting satellite served as a stabilized, earth-oriented platform for the testing of advanced systems for sensing and collecting data in the pollution, oceanographic and meteorological disciplines. It was launched on October 24, 1978." }, "instrument": { "ob_id": 2636, "uuid": "1578228cc3cf4b9fba0b88c61b58800b", "short_code": "instr", "title": "Scanning Multichannel Microwave Radiometer (SMMR)", "abstract": "The Scanning Multichannel Microwave Radiometer operated on NASA's Nimbus-7 satellite for more than eight years, from 26 October 1978 to 20 August 1987, transmitting data every other day. Intended to obtain ocean circulation parameters such as sea surface temperatures, low altitude winds, water vapor and cloud liquid water content on an all-weather basis, the SMMR is a ten channel instrument capable of receiving both horizontally and vertically polarized radiation. A parabolic antenna 79 cm in diameter reflected microwave emissions into a five-frequency feed horn. The antenna beam maintained a constant nadir angle of 42 degrees, resulting in an incidence angle of 50.3 degrees at Earth's surface. The antenna was forward viewing and rotated equally +/- 25 degrees about the satellite subtrack. The 50 degree scan provided a 780 km swath of the Earth's surface. Scan period was 4.096 seconds." }, "relatedTo": { "ob_id": 32227, "uuid": "c58157eefd194b0c993d2dc767e6e846", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.3", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12462, "platform": { "ob_id": 2629, "uuid": "9f1b0a2380cc47919b201880e0fee6de", "short_code": "plat", "title": "Defense Meteorological Satellite Program (DMSP) Satellites", "abstract": "DMSP satellites are used for strategic and tactical weather prediction to aid the U.S. military in planning operations at sea, on land and in the air. Equipped with a sophisticated sensor suite that can image visible and infrared cloud cover and measure precipitation, surface temperature, and soil moisture, the satellite collects specialized global meteorological, oceanographic, and solar-geophysical information in all weather conditions. The DMSP constellation comprises two spacecraft in near-polar orbits, C3 (command, control and communications), user terminals and weather centers." }, "instrument": { "ob_id": 2630, "uuid": "54f897597ec04c09b01095eb05c7419e", "short_code": "instr", "title": "Special Sensor Microwave / Imager (SSM/I)", "abstract": "The SSM/I is a seven-channel, four frequency, linearly-polarized, passive microwave radiometric system which measures atmospheric, ocean and terrain microwave brightness temperatures at 19.35, 22.235, 37.0 and 85.5 GHz. The data are used to obtain synoptic maps of critical atmospheric, oceanographic and selected land parameters on a global scale." }, "relatedTo": { "ob_id": 32227, "uuid": "c58157eefd194b0c993d2dc767e6e846", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.3", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12463, "platform": { "ob_id": 27135, "uuid": "8afe985a2f3f4b15aaa52df6119c0f27", "short_code": "plat", "title": "TRMM", "abstract": "The Tropical Rainfall Measuring Mission (TRMM) is a NASA and JAXA satellite that flew between 1997 and 2015. It's primary mission was to measure precipitation." }, "instrument": { "ob_id": 27126, "uuid": "9173171ba44845e9a873e21b4dee19e2", "short_code": "instr", "title": "TMI", "abstract": "TMI (TRMM Microwave Imager) is a multi-purpose microwave imager flying on the TRMM (Tropical Rainfall Measuring Mission)." }, "relatedTo": { "ob_id": 32227, "uuid": "c58157eefd194b0c993d2dc767e6e846", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.3", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12464, "platform": { "ob_id": 10906, "uuid": "5a1076bffc8c4c5d8a2ff3a4cfb29846", "short_code": "plat", "title": "Aqua Satellite, part of the Earth Observation System Afternoon Constellation (EOS-PM)", "abstract": "Aqua, launched on 4th April 2002, is a polar-orbiting satellite within the Afternoon Constellation (A-Train) that have equator crossings around 13:30 and 01:30 under NASA's Earth Obseration System (EOS). The satellite carries Atmospheric Infrared Sounder (AIRS), Advanced Microwave Sounding Unit (AMSU-A), Humidity Sounder for Brazil (HSB), Advanced Microwave Scanning Radiometer for EOS (AMSR-E), Moderate-Resolution Imaging Spectroradiometer (MODIS) and Clouds and the Earth's Radiant Energy System (CERES), and these collect data on the Earth's atmospheric conditions, snow and ice, sea surface temperature and ocean productivity, and soil moisture. Aqua was the first member launched of a group of satellites termed the Afternoon Constellation, or sometimes the A-Train. " }, "instrument": { "ob_id": 14485, "uuid": "77dd26fc341a440b85a98fe95b1976f8", "short_code": "instr", "title": "AMSR-E", "abstract": "Advanced Microwave Scanning Radiometer for EOS" }, "relatedTo": { "ob_id": 32227, "uuid": "c58157eefd194b0c993d2dc767e6e846", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.3", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12465, "platform": { "ob_id": 25273, "uuid": "f10d619f7b9f4dbab792dcc1ab9dbb68", "short_code": "plat", "title": "GCOM-W (Global Change Observation Mission for Water)", "abstract": "The Global Change Observation Mission for Water (GCOM-W) is a series of three satellites flown by the Japanese Space Agency (JAXA), addressing multi-purpose MW imagery for ocean, land and precipitation. It is part of their Global Change Observation Mission (GCOM).\r\nThe satellites exploit sun-synchronous orbits around 13:30, coordinated with that of POES satellites, Suomi-NPP and JPSS." }, "instrument": { "ob_id": 25272, "uuid": "a6002da7c0954ce0aa146c1b24877a0a", "short_code": "instr", "title": "AMSR-2", "abstract": "Advanced Microwave Scanning Radiometer -2, flying on the Global Change Observation Mission (GCOM) series of satellites flown by JAXA" }, "relatedTo": { "ob_id": 32227, "uuid": "c58157eefd194b0c993d2dc767e6e846", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.3", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12466, "platform": { "ob_id": 27130, "uuid": "526c6fb02e094d049d367aaa4f79e8d1", "short_code": "plat", "title": "Coriolis", "abstract": "The Coriolis satellite is flown by NASA and the US Department of Defence, with a primary mission to provide observations of the sea-surface wind. It carries two instruments: WindSat and SMEI (Solar Mass Ejection Imager)" }, "instrument": { "ob_id": 27125, "uuid": "10f4aca379f84e0cae56392a85604469", "short_code": "instr", "title": "WindSat", "abstract": "WindSat is a passive microwave radiometer flown on the Coriolis Satellite by the US Department of Defence since 2003." }, "relatedTo": { "ob_id": 32227, "uuid": "c58157eefd194b0c993d2dc767e6e846", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.3", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12467, "platform": { "ob_id": 27128, "uuid": "9c6e8c73f539446ba7a8adef871492a7", "short_code": "plat", "title": "SMOS", "abstract": "The SMOS (Soil Moisture and Ocean Salinity) satellite was launched on Novermber 2009, with the primary mission to monitor ocean salinity and soil moisture." }, "instrument": { "ob_id": 27124, "uuid": "9b4be0d67030450ca8aebf37cf39500c", "short_code": "instr", "title": "MIRAS", "abstract": "MIRAS (Microwave Imaging Radiometer using Aperture Synthesis) is an European Space Agency instrument flown on the SMOS (Soil Moisture and Ocean Salinity) Satellite. It measures Ocean Salinity and Soil Moisture." }, "relatedTo": { "ob_id": 32227, "uuid": "c58157eefd194b0c993d2dc767e6e846", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.3", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } }, { "ob_id": 12468, "platform": { "ob_id": 29941, "uuid": "2b126b39dbb64c0681f12b68f2308fee", "short_code": "plat", "title": "SMAP", "abstract": "The Soil Moisture Active-Passive (SMAP) satelliteis a NASA satellite launched in 2015." }, "instrument": { "ob_id": 29938, "uuid": "e050ad22e3b943f9a5f1563a1e6fb82c", "short_code": "instr", "title": "SMAP", "abstract": "The Soil Moisture Active Passive instrument is a microwave radiometer flown on the NASA SMAP satellite." }, "relatedTo": { "ob_id": 32227, "uuid": "c58157eefd194b0c993d2dc767e6e846", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v05.3", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS) and SMAP satellite instruments." } } ] }, { "ob_id": 32228, "uuid": "65efe382488a493fa196c0313d42649f", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.3", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 460, "uuid": "bea2c6443d2f4f81a2701f09cb4e6f5c", "short_code": "mpop", "title": "Mobile Platform Operation for: NIMBUS 7 Satellite", "abstract": "Mobile Platform Operation related to the: NIMBUS 7 Satellite" }, { "ob_id": 2631, "uuid": "4647e36325d544eca3db5d8795c216c6", "short_code": "mpop", "title": "Mobile Platform Operation for: Defense Meteorological Satellite Program (DMSP) Satellites", "abstract": "Mobile Platform Operation related to the: Defense Meteorological Satellite Program (DMSP) Satellites" }, { "ob_id": 7807, "uuid": "a27cd0df0a124f2ca5873877e21f637e", "short_code": "mpop", "title": "Mobile Platform Operation for: ERS-1", "abstract": "Mobile Platform Operation related to the: ERS-1" }, { "ob_id": 7814, "uuid": "ae416a28a96049e7bf33ea668c187852", "short_code": "mpop", "title": "Mobile Platform Operation for: ERS-2", "abstract": "Mobile Platform Operation related to the: ERS-2" }, { "ob_id": 8209, "uuid": "f0f061d64cca41c3a4221b713fd6b1be", "short_code": "mpop", "title": "Mobile Platform Operation for: Metop-A", "abstract": "Mobile Platform Operation related to the: Metop-A" }, { "ob_id": 8301, "uuid": "d1d4ffcf747d4e95a3614aa20f1855da", "short_code": "mpop", "title": "Mobile Platform Operation for: Metop-B", "abstract": "Mobile Platform Operation related to the: Metop-B" }, { "ob_id": 10907, "uuid": "1be652a219874193976dff38a64fc180", "short_code": "mpop", "title": "Aqua Satellite orbit details", "abstract": "NASA's AQUA (EOS-PM1) is a sun-synchronous, polar orbiting satellite in an afternoon orbit, with equator crossing times of approximately 13:30 and 01:30. It forms part of the A-train, a collection of satellites orbiting close together along the same orbital track" }, { "ob_id": 27132, "uuid": "6c74884699f541ff8a1edb33933ddada", "short_code": "mpop", "title": "Coriolis Satellite Orbit Details", "abstract": "The Coriolis Satellite is flown by NASA and the US Department of Defence and is in a Sunsynchronous orbit with an 06.10 descending equator crossing time." }, { "ob_id": 27133, "uuid": "c15fb49dfbf24bdc81acb5ae16df1b1d", "short_code": "mpop", "title": "SMOS satellite orbit details", "abstract": "The SMOS satellite is operated by ESA and is in a sunscynchronous orbit with a 06:00 ascending equator crossing time." }, { "ob_id": 27137, "uuid": "f6550c6efe0c4a9baaf3c5d07627b2ed", "short_code": "mpop", "title": "GCOM-W satellite orbit details", "abstract": "The GCOM-W (Global Change Observation Mission for Water) is a JAXA satellite in a sunsynchronous orbit with a 13.30 ascending equator crossing time." }, { "ob_id": 27138, "uuid": "44f2493522254d2696575ce3acb6146c", "short_code": "mpop", "title": "TRMM satellite orbit details", "abstract": "The TRMM (Tropical Rainfall Measuring Mission) is a NASA, JAXA satellite mission. It is in a drifting orbit with an inclination of 35 degrees and altitude of 402 km." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12469, "platform": { "ob_id": 27128, "uuid": "9c6e8c73f539446ba7a8adef871492a7", "short_code": "plat", "title": "SMOS", "abstract": "The SMOS (Soil Moisture and Ocean Salinity) satellite was launched on Novermber 2009, with the primary mission to monitor ocean salinity and soil moisture." }, "instrument": { "ob_id": 27124, "uuid": "9b4be0d67030450ca8aebf37cf39500c", "short_code": "instr", "title": "MIRAS", "abstract": "MIRAS (Microwave Imaging Radiometer using Aperture Synthesis) is an European Space Agency instrument flown on the SMOS (Soil Moisture and Ocean Salinity) Satellite. It measures Ocean Salinity and Soil Moisture." }, "relatedTo": { "ob_id": 32228, "uuid": "65efe382488a493fa196c0313d42649f", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.3", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12470, "platform": { "ob_id": 27130, "uuid": "526c6fb02e094d049d367aaa4f79e8d1", "short_code": "plat", "title": "Coriolis", "abstract": "The Coriolis satellite is flown by NASA and the US Department of Defence, with a primary mission to provide observations of the sea-surface wind. It carries two instruments: WindSat and SMEI (Solar Mass Ejection Imager)" }, "instrument": { "ob_id": 27125, "uuid": "10f4aca379f84e0cae56392a85604469", "short_code": "instr", "title": "WindSat", "abstract": "WindSat is a passive microwave radiometer flown on the Coriolis Satellite by the US Department of Defence since 2003." }, "relatedTo": { "ob_id": 32228, "uuid": "65efe382488a493fa196c0313d42649f", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.3", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12471, "platform": { "ob_id": 25273, "uuid": "f10d619f7b9f4dbab792dcc1ab9dbb68", "short_code": "plat", "title": "GCOM-W (Global Change Observation Mission for Water)", "abstract": "The Global Change Observation Mission for Water (GCOM-W) is a series of three satellites flown by the Japanese Space Agency (JAXA), addressing multi-purpose MW imagery for ocean, land and precipitation. It is part of their Global Change Observation Mission (GCOM).\r\nThe satellites exploit sun-synchronous orbits around 13:30, coordinated with that of POES satellites, Suomi-NPP and JPSS." }, "instrument": { "ob_id": 25272, "uuid": "a6002da7c0954ce0aa146c1b24877a0a", "short_code": "instr", "title": "AMSR-2", "abstract": "Advanced Microwave Scanning Radiometer -2, flying on the Global Change Observation Mission (GCOM) series of satellites flown by JAXA" }, "relatedTo": { "ob_id": 32228, "uuid": "65efe382488a493fa196c0313d42649f", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.3", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12472, "platform": { "ob_id": 10906, "uuid": "5a1076bffc8c4c5d8a2ff3a4cfb29846", "short_code": "plat", "title": "Aqua Satellite, part of the Earth Observation System Afternoon Constellation (EOS-PM)", "abstract": "Aqua, launched on 4th April 2002, is a polar-orbiting satellite within the Afternoon Constellation (A-Train) that have equator crossings around 13:30 and 01:30 under NASA's Earth Obseration System (EOS). The satellite carries Atmospheric Infrared Sounder (AIRS), Advanced Microwave Sounding Unit (AMSU-A), Humidity Sounder for Brazil (HSB), Advanced Microwave Scanning Radiometer for EOS (AMSR-E), Moderate-Resolution Imaging Spectroradiometer (MODIS) and Clouds and the Earth's Radiant Energy System (CERES), and these collect data on the Earth's atmospheric conditions, snow and ice, sea surface temperature and ocean productivity, and soil moisture. Aqua was the first member launched of a group of satellites termed the Afternoon Constellation, or sometimes the A-Train. " }, "instrument": { "ob_id": 14485, "uuid": "77dd26fc341a440b85a98fe95b1976f8", "short_code": "instr", "title": "AMSR-E", "abstract": "Advanced Microwave Scanning Radiometer for EOS" }, "relatedTo": { "ob_id": 32228, "uuid": "65efe382488a493fa196c0313d42649f", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.3", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12473, "platform": { "ob_id": 27135, "uuid": "8afe985a2f3f4b15aaa52df6119c0f27", "short_code": "plat", "title": "TRMM", "abstract": "The Tropical Rainfall Measuring Mission (TRMM) is a NASA and JAXA satellite that flew between 1997 and 2015. It's primary mission was to measure precipitation." }, "instrument": { "ob_id": 27126, "uuid": "9173171ba44845e9a873e21b4dee19e2", "short_code": "instr", "title": "TMI", "abstract": "TMI (TRMM Microwave Imager) is a multi-purpose microwave imager flying on the TRMM (Tropical Rainfall Measuring Mission)." }, "relatedTo": { "ob_id": 32228, "uuid": "65efe382488a493fa196c0313d42649f", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.3", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12474, "platform": { "ob_id": 2629, "uuid": "9f1b0a2380cc47919b201880e0fee6de", "short_code": "plat", "title": "Defense Meteorological Satellite Program (DMSP) Satellites", "abstract": "DMSP satellites are used for strategic and tactical weather prediction to aid the U.S. military in planning operations at sea, on land and in the air. Equipped with a sophisticated sensor suite that can image visible and infrared cloud cover and measure precipitation, surface temperature, and soil moisture, the satellite collects specialized global meteorological, oceanographic, and solar-geophysical information in all weather conditions. The DMSP constellation comprises two spacecraft in near-polar orbits, C3 (command, control and communications), user terminals and weather centers." }, "instrument": { "ob_id": 2630, "uuid": "54f897597ec04c09b01095eb05c7419e", "short_code": "instr", "title": "Special Sensor Microwave / Imager (SSM/I)", "abstract": "The SSM/I is a seven-channel, four frequency, linearly-polarized, passive microwave radiometric system which measures atmospheric, ocean and terrain microwave brightness temperatures at 19.35, 22.235, 37.0 and 85.5 GHz. The data are used to obtain synoptic maps of critical atmospheric, oceanographic and selected land parameters on a global scale." }, "relatedTo": { "ob_id": 32228, "uuid": "65efe382488a493fa196c0313d42649f", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.3", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12475, "platform": { "ob_id": 458, "uuid": "b6d87ac1455348cd97a4386b38995dbb", "short_code": "plat", "title": "NIMBUS 7 Satellite", "abstract": "The NASA Nimbus 7 research-and-development polar-orbiting satellite served as a stabilized, earth-oriented platform for the testing of advanced systems for sensing and collecting data in the pollution, oceanographic and meteorological disciplines. It was launched on October 24, 1978." }, "instrument": { "ob_id": 2636, "uuid": "1578228cc3cf4b9fba0b88c61b58800b", "short_code": "instr", "title": "Scanning Multichannel Microwave Radiometer (SMMR)", "abstract": "The Scanning Multichannel Microwave Radiometer operated on NASA's Nimbus-7 satellite for more than eight years, from 26 October 1978 to 20 August 1987, transmitting data every other day. Intended to obtain ocean circulation parameters such as sea surface temperatures, low altitude winds, water vapor and cloud liquid water content on an all-weather basis, the SMMR is a ten channel instrument capable of receiving both horizontally and vertically polarized radiation. A parabolic antenna 79 cm in diameter reflected microwave emissions into a five-frequency feed horn. The antenna beam maintained a constant nadir angle of 42 degrees, resulting in an incidence angle of 50.3 degrees at Earth's surface. The antenna was forward viewing and rotated equally +/- 25 degrees about the satellite subtrack. The 50 degree scan provided a 780 km swath of the Earth's surface. Scan period was 4.096 seconds." }, "relatedTo": { "ob_id": 32228, "uuid": "65efe382488a493fa196c0313d42649f", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.3", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12476, "platform": { "ob_id": 8207, "uuid": "3f2dbe69fe4c40ee9e1e8be87e15a1d5", "short_code": "plat", "title": "Metop-A", "abstract": "Metop-A, launched on 19 October 2006, represents the first in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS). Metop-A is Europe's first polar-orbiting meteorological satellite" }, "instrument": { "ob_id": 27121, "uuid": "ca133e0771514003a9e7c2462c1b363c", "short_code": "instr", "title": "ASCAT", "abstract": "ASCAT (Advanced Scatterometer) is a C Band (2.55 GHz) Scatterometer flown on the Metop series of satellites. It measures the sea surface wind vecotr and large-scale soil moisture." }, "relatedTo": { "ob_id": 32228, "uuid": "65efe382488a493fa196c0313d42649f", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.3", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12477, "platform": { "ob_id": 8299, "uuid": "84a6355ac58249cc8c636e77a243c86a", "short_code": "plat", "title": "Metop-B", "abstract": "Metop-B, launched on the 17th September 2012, is the second in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS)." }, "instrument": { "ob_id": 27121, "uuid": "ca133e0771514003a9e7c2462c1b363c", "short_code": "instr", "title": "ASCAT", "abstract": "ASCAT (Advanced Scatterometer) is a C Band (2.55 GHz) Scatterometer flown on the Metop series of satellites. It measures the sea surface wind vecotr and large-scale soil moisture." }, "relatedTo": { "ob_id": 32228, "uuid": "65efe382488a493fa196c0313d42649f", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.3", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12478, "platform": { "ob_id": 7805, "uuid": "d21630e98aa74a4f8406743b74e5d076", "short_code": "plat", "title": "ERS-1", "abstract": "The European Remote Sensing satellite 1 (ERS1) was launched on 17th July 1991 and was the first flight of the RSA ERS program. The payload included the ATSR, AMU-SAR , AMI-SCAT, LRR PRARE and RA instruments. End of mission for ERS1 was 10th March 2000." }, "instrument": { "ob_id": 27122, "uuid": "7b488736a173477689480990d5b38aa9", "short_code": "instr", "title": "AMI-SCAT", "abstract": "AMI-SCAT (Active Microwave Instrument - Scatterometer) is a C-band (5.3 GHz) scatterometer flying on the ERS-1 and ERS-2 satellites. It measures the sea surface wind vector and large-scale soil moisture." }, "relatedTo": { "ob_id": 32228, "uuid": "65efe382488a493fa196c0313d42649f", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.3", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12479, "platform": { "ob_id": 7813, "uuid": "8ee876e1ea644ed7a81d4e3536133fa0", "short_code": "plat", "title": "European Remote Sensing satellite 2 - ERS-2", "abstract": "ESA's two European Remote Sensing (ERS) satellites, ERS-1 and –2, were launched into the same orbit in 1991 and 1995 respectively. Their payloads included a synthetic aperture imaging radar, radar altimeter and instruments to measure ocean surface temperature and wind fields.\r\n\r\nERS-2 added an additional sensor for atmospheric ozone monitoring. The two satellites acquired a combined data set extending over two decades.\r\n\r\nThe ERS-2 satellite was retired on 05 September 2011." }, "instrument": { "ob_id": 27122, "uuid": "7b488736a173477689480990d5b38aa9", "short_code": "instr", "title": "AMI-SCAT", "abstract": "AMI-SCAT (Active Microwave Instrument - Scatterometer) is a C-band (5.3 GHz) scatterometer flying on the ERS-1 and ERS-2 satellites. It measures the sea surface wind vector and large-scale soil moisture." }, "relatedTo": { "ob_id": 32228, "uuid": "65efe382488a493fa196c0313d42649f", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.3", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } }, { "ob_id": 12480, "platform": { "ob_id": 29941, "uuid": "2b126b39dbb64c0681f12b68f2308fee", "short_code": "plat", "title": "SMAP", "abstract": "The Soil Moisture Active-Passive (SMAP) satelliteis a NASA satellite launched in 2015." }, "instrument": { "ob_id": 29938, "uuid": "e050ad22e3b943f9a5f1563a1e6fb82c", "short_code": "instr", "title": "SMAP", "abstract": "The Soil Moisture Active Passive instrument is a microwave radiometer flown on the NASA SMAP satellite." }, "relatedTo": { "ob_id": 32228, "uuid": "65efe382488a493fa196c0313d42649f", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v5.3", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS) and SMAP)" } } ] }, { "ob_id": 32229, "uuid": "a1bf27d8c7324fd89e2a5ae24d92aa20", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v05.3", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments.", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 8209, "uuid": "f0f061d64cca41c3a4221b713fd6b1be", "short_code": "mpop", "title": "Mobile Platform Operation for: Metop-A", "abstract": "Mobile Platform Operation related to the: Metop-A" }, { "ob_id": 8301, "uuid": "d1d4ffcf747d4e95a3614aa20f1855da", "short_code": "mpop", "title": "Mobile Platform Operation for: Metop-B", "abstract": "Mobile Platform Operation related to the: Metop-B" }, { "ob_id": 7814, "uuid": "ae416a28a96049e7bf33ea668c187852", "short_code": "mpop", "title": "Mobile Platform Operation for: ERS-2", "abstract": "Mobile Platform Operation related to the: ERS-2" }, { "ob_id": 7807, "uuid": "a27cd0df0a124f2ca5873877e21f637e", "short_code": "mpop", "title": "Mobile Platform Operation for: ERS-1", "abstract": "Mobile Platform Operation related to the: ERS-1" } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12481, "platform": { "ob_id": 8207, "uuid": "3f2dbe69fe4c40ee9e1e8be87e15a1d5", "short_code": "plat", "title": "Metop-A", "abstract": "Metop-A, launched on 19 October 2006, represents the first in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS). Metop-A is Europe's first polar-orbiting meteorological satellite" }, "instrument": { "ob_id": 27121, "uuid": "ca133e0771514003a9e7c2462c1b363c", "short_code": "instr", "title": "ASCAT", "abstract": "ASCAT (Advanced Scatterometer) is a C Band (2.55 GHz) Scatterometer flown on the Metop series of satellites. It measures the sea surface wind vecotr and large-scale soil moisture." }, "relatedTo": { "ob_id": 32229, "uuid": "a1bf27d8c7324fd89e2a5ae24d92aa20", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v05.3", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments." } }, { "ob_id": 12482, "platform": { "ob_id": 8299, "uuid": "84a6355ac58249cc8c636e77a243c86a", "short_code": "plat", "title": "Metop-B", "abstract": "Metop-B, launched on the 17th September 2012, is the second in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS)." }, "instrument": { "ob_id": 27121, "uuid": "ca133e0771514003a9e7c2462c1b363c", "short_code": "instr", "title": "ASCAT", "abstract": "ASCAT (Advanced Scatterometer) is a C Band (2.55 GHz) Scatterometer flown on the Metop series of satellites. It measures the sea surface wind vecotr and large-scale soil moisture." }, "relatedTo": { "ob_id": 32229, "uuid": "a1bf27d8c7324fd89e2a5ae24d92aa20", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v05.3", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments." } }, { "ob_id": 12483, "platform": { "ob_id": 7805, "uuid": "d21630e98aa74a4f8406743b74e5d076", "short_code": "plat", "title": "ERS-1", "abstract": "The European Remote Sensing satellite 1 (ERS1) was launched on 17th July 1991 and was the first flight of the RSA ERS program. The payload included the ATSR, AMU-SAR , AMI-SCAT, LRR PRARE and RA instruments. End of mission for ERS1 was 10th March 2000." }, "instrument": { "ob_id": 27122, "uuid": "7b488736a173477689480990d5b38aa9", "short_code": "instr", "title": "AMI-SCAT", "abstract": "AMI-SCAT (Active Microwave Instrument - Scatterometer) is a C-band (5.3 GHz) scatterometer flying on the ERS-1 and ERS-2 satellites. It measures the sea surface wind vector and large-scale soil moisture." }, "relatedTo": { "ob_id": 32229, "uuid": "a1bf27d8c7324fd89e2a5ae24d92aa20", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v05.3", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments." } }, { "ob_id": 12484, "platform": { "ob_id": 7813, "uuid": "8ee876e1ea644ed7a81d4e3536133fa0", "short_code": "plat", "title": "European Remote Sensing satellite 2 - ERS-2", "abstract": "ESA's two European Remote Sensing (ERS) satellites, ERS-1 and –2, were launched into the same orbit in 1991 and 1995 respectively. Their payloads included a synthetic aperture imaging radar, radar altimeter and instruments to measure ocean surface temperature and wind fields.\r\n\r\nERS-2 added an additional sensor for atmospheric ozone monitoring. The two satellites acquired a combined data set extending over two decades.\r\n\r\nThe ERS-2 satellite was retired on 05 September 2011." }, "instrument": { "ob_id": 27122, "uuid": "7b488736a173477689480990d5b38aa9", "short_code": "instr", "title": "AMI-SCAT", "abstract": "AMI-SCAT (Active Microwave Instrument - Scatterometer) is a C-band (5.3 GHz) scatterometer flying on the ERS-1 and ERS-2 satellites. It measures the sea surface wind vector and large-scale soil moisture." }, "relatedTo": { "ob_id": 32229, "uuid": "a1bf27d8c7324fd89e2a5ae24d92aa20", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v05.3", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments." } } ] }, { "ob_id": 32249, "uuid": "4080684074cc4546af0345f958b27c78", "short_code": "acq", "title": "APHH: Atmospheric NO, NO2 and NOx measurements made at Indian Institute of Technology (IIT) Delhi", "abstract": "APHH: Atmospheric NO, NO2 and NOx measurements made at Indian Institute of Technology (IIT) Delhi", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12485, "platform": { "ob_id": 31552, "uuid": "a73fd81eacbd48858d36ed5be3d45eb3", "short_code": "plat", "title": "Indian Institute of Technology, Delhi, India", "abstract": "Used in APHH ASAP-Delhi project" }, "instrument": { "ob_id": 32247, "uuid": "17976ef33f9b43cc8f8a190807ec2474", "short_code": "instr", "title": "Thermo Environmental Instruments 42C NO-NO2-NOx level Analyser", "abstract": "Thermo Environmental Instruments 42C NO-NO2-NOx level Analyser" }, "relatedTo": { "ob_id": 32249, "uuid": "4080684074cc4546af0345f958b27c78", "short_code": "acq", "title": "APHH: Atmospheric NO, NO2 and NOx measurements made at Indian Institute of Technology (IIT) Delhi", "abstract": "APHH: Atmospheric NO, NO2 and NOx measurements made at Indian Institute of Technology (IIT) Delhi" } } ] }, { "ob_id": 32252, "uuid": "f7df28bb36e54f2682fcb57e0c3a453a", "short_code": "acq", "title": "APHH: Atmospheric black carbon measurements made at Indira Gandhi Delhi Technical University for Women (IGDTUW)", "abstract": "APHH: Atmospheric black carbon measurements made at Indira Gandhi Delhi Technical University for Women (IGDTUW)", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12486, "platform": { "ob_id": 30219, "uuid": "07a71f4e62e2468391f492b85905167c", "short_code": "plat", "title": "Indira Gandhi Delhi Technical University for Women (IGDTUW)", "abstract": "Indira Gandhi Delhi Technical University for Women (IGDTUW) which is situated on the periphery of Old Delhi and overlooks a very heavily populated area. As part of the DelhiFlux project the team have constructed a rooftop mast at 4m and a 30 m tall flux tower from which to directly measure pollutant emissions from two contrasting regions of Delhi." }, "instrument": { "ob_id": 11751, "uuid": "534ceb3b8838e05472867fc5a3c2a4a4", "short_code": "instr", "title": "Aethalometer", "abstract": "Instrument.abstract: DETAILS NEEDED" }, "relatedTo": { "ob_id": 32252, "uuid": "f7df28bb36e54f2682fcb57e0c3a453a", "short_code": "acq", "title": "APHH: Atmospheric black carbon measurements made at Indira Gandhi Delhi Technical University for Women (IGDTUW)", "abstract": "APHH: Atmospheric black carbon measurements made at Indira Gandhi Delhi Technical University for Women (IGDTUW)" } } ] }, { "ob_id": 32256, "uuid": "2f3d0753753644048002896db05ebc10", "short_code": "acq", "title": "APHH: Atmospheric O3 measurements made at Indian Institute of Technology (IIT) Delhi", "abstract": "APHH: Atmospheric O3 measurements made at Indian Institute of Technology (IIT) Delhi", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12487, "platform": { "ob_id": 31552, "uuid": "a73fd81eacbd48858d36ed5be3d45eb3", "short_code": "plat", "title": "Indian Institute of Technology, Delhi, India", "abstract": "Used in APHH ASAP-Delhi project" }, "instrument": { "ob_id": 32255, "uuid": "98377fc8a1b44494ae96b81264c679e2", "short_code": "instr", "title": "Thermo Scientific 49i Ozone Analyser", "abstract": "The Thermo Scientific Model 49i Ozone Analyzer utilizes UV photometric technology to measure the amount of ozone in the air." }, "relatedTo": { "ob_id": 32256, "uuid": "2f3d0753753644048002896db05ebc10", "short_code": "acq", "title": "APHH: Atmospheric O3 measurements made at Indian Institute of Technology (IIT) Delhi", "abstract": "APHH: Atmospheric O3 measurements made at Indian Institute of Technology (IIT) Delhi" } } ] }, { "ob_id": 32274, "uuid": "a258b0fde4aa4c1290bb8cc1ff00e13b", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2019_168 - HyTES19 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 32275, "uuid": "4e0e67f525184a0081e607c2c15f4707", "short_code": "mpop", "title": "ARSF flight 2019_168", "abstract": "Flight details for NERC-ARSF aircraft flight number 2019_168. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12488, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 32274, "uuid": "a258b0fde4aa4c1290bb8cc1ff00e13b", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2019_168 - HyTES19 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 32279, "uuid": "0073a759d788485cb3e3f4ac0573120b", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2019_169 - HyTES19 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 32280, "uuid": "380f9c7afcc643968fc995be7554bc83", "short_code": "mpop", "title": "ARSF flight 2019_169", "abstract": "Flight details for NERC-ARSF aircraft flight number 2019_169. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12489, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 32279, "uuid": "0073a759d788485cb3e3f4ac0573120b", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2019_169 - HyTES19 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 32284, "uuid": "d1f8c4c3ea4747d79ad949afbf2a24d1", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative ATSR2-AATSR datasets", "abstract": "The ESA Cloud Climate Change Initiative ATSR2-AATSR datasets are based on data from the Along Track Scanning Radiometer - 2 (ATSR-2) and Advanced Along Track Scanning Radiometer (AATSR).", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12490, "platform": { "ob_id": 7813, "uuid": "8ee876e1ea644ed7a81d4e3536133fa0", "short_code": "plat", "title": "European Remote Sensing satellite 2 - ERS-2", "abstract": "ESA's two European Remote Sensing (ERS) satellites, ERS-1 and –2, were launched into the same orbit in 1991 and 1995 respectively. Their payloads included a synthetic aperture imaging radar, radar altimeter and instruments to measure ocean surface temperature and wind fields.\r\n\r\nERS-2 added an additional sensor for atmospheric ozone monitoring. The two satellites acquired a combined data set extending over two decades.\r\n\r\nThe ERS-2 satellite was retired on 05 September 2011." }, "instrument": { "ob_id": 5566, "uuid": "0144096c6dd84a2a99abced27e129e12", "short_code": "instr", "title": "Along Track Scanning Radiometer 2 (ATSR-2)", "abstract": "An enhanced version of ATSR (Along Track Scanning Radiometer), ATSR-2, was successfully launched on board the European Space Agency (ESA) ERS-2 (European Remote Sensing - 2) spacecraft on 21st April 1995. ATSR-2 is equipped with additional visible channels for vegetation monitoring. It measures sea surface temperatures and the vegetation cover of land surfaces." }, "relatedTo": { "ob_id": 32284, "uuid": "d1f8c4c3ea4747d79ad949afbf2a24d1", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative ATSR2-AATSR datasets", "abstract": "The ESA Cloud Climate Change Initiative ATSR2-AATSR datasets are based on data from the Along Track Scanning Radiometer - 2 (ATSR-2) and Advanced Along Track Scanning Radiometer (AATSR)." } }, { "ob_id": 12495, "platform": { "ob_id": 846, "uuid": "47779e22cdc6491a9f7491af866f7080", "short_code": "plat", "title": "Envisat", "abstract": "In March 2002, the European Space Agency launched Envisat, an advanced polar-orbiting Earth observation satellite which provides measurements of the atmosphere, ocean, land, and ice. The Envisat satellite has a payload of 10 instruments that will ensure the continuity of the data measurements of the ESA ERS satellites. Envisat data supports earth science research and allows monitoring of the evolution of environmental and climatic changes.\r\n\r\nLaunch date: 01/03/2002\r\nStatus / projected mission lifetime: Terminated on 08/04/2012\r\nOrbit parameters: 30 km in front of ERS2\r\nNominal altitude: 800 km (same as ERS2, near circular)\r\nOrbit type: near-polar, sun-synchronous\r\nInclination: 98.55 degrees\r\nRepeat period: 35 days\r\nEquatorial crossing time: 10:00 local time (descending node)\r\nSwath width: various\r\nResolution: various" }, "instrument": { "ob_id": 847, "uuid": "e448141cadd04550aa19dac5601af34d", "short_code": "instr", "title": "Advanced Along-Track Scanning Radiometer (AATSR)", "abstract": "The Advanced Along-Track Scanning Radiometer (AATSR) measures global Sea Surface Temperature (SST) from space to the highest possible levels of accuracy and stability, as required for climate research and monitoring. It is the third in the ATSR series, and is a payload instrument on ESA's ENVISAT." }, "relatedTo": { "ob_id": 32284, "uuid": "d1f8c4c3ea4747d79ad949afbf2a24d1", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative ATSR2-AATSR datasets", "abstract": "The ESA Cloud Climate Change Initiative ATSR2-AATSR datasets are based on data from the Along Track Scanning Radiometer - 2 (ATSR-2) and Advanced Along Track Scanning Radiometer (AATSR)." } } ] }, { "ob_id": 32290, "uuid": "90a4f8cf26f24106a92d88db9f21a7e8", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative AVHRR-AM datasets", "abstract": "The ESA Cloud Climate Change Initiative AVHRR-AM datasets are based on intercalibrated measurements form the Advanced Very High Resolution Radiometer (AVHRR) sensors on-board the NOAA prime morning (AM) satellite NOAA-12,-15,-17, and the EUMETSAT Metop-A satellite.", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12491, "platform": { "ob_id": 1801, "uuid": "899ad53a29ea4232888f2d021dd988d3", "short_code": "plat", "title": "NOAA-12", "abstract": "NASA polar orbiting satellite which was launched on May 14, 1991 remained operational until April 2001." }, "instrument": { "ob_id": 1802, "uuid": "adfffcff783c4b26ac9640ef4b141196", "short_code": "instr", "title": "Advanced Very High Resolution Radiometer 2 (AVHRR/2)", "abstract": "The AVHRR is a radiation-detection imager that can be used for remotely determining cloud cover and the surface temperature. Note that the term surface can mean the surface of the Earth, the upper surfaces of clouds, or the surface of a body of water. This scanning radiometer uses 6 detectors that collect different bands of radiation wavelengths.\n\nThe first AVHRR was a 4-channel radiometer, first carried on TIROS-N (launched October 1978). This was subsequently improved to a 5-channel instrument (AVHRR/2) that was initially carried on NOAA-7 (launched June 1981). The latest instrument version is AVHRR/3, with 6 channels, first carried on NOAA-15 launched in May 1998." }, "relatedTo": { "ob_id": 32290, "uuid": "90a4f8cf26f24106a92d88db9f21a7e8", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative AVHRR-AM datasets", "abstract": "The ESA Cloud Climate Change Initiative AVHRR-AM datasets are based on intercalibrated measurements form the Advanced Very High Resolution Radiometer (AVHRR) sensors on-board the NOAA prime morning (AM) satellite NOAA-12,-15,-17, and the EUMETSAT Metop-A satellite." } }, { "ob_id": 12492, "platform": { "ob_id": 1816, "uuid": "a6fa2998eb0246b4a699a0753c74a2f3", "short_code": "plat", "title": "NOAA-15", "abstract": "NOAA polar orbiting satellite which was launched on May 13, 1998 and is still operational to this date." }, "instrument": { "ob_id": 1817, "uuid": "eff26a2de66b4c6b9f71a15e875f52c5", "short_code": "instr", "title": "Advanced Very High Resolution Radiometer 3 (AVHRR/3)", "abstract": "The AVHRR is a radiation-detection imager that can be used for remotely determining cloud cover and the surface temperature. Note that the term surface can mean the surface of the Earth, the upper surfaces of clouds, or the surface of a body of water. This scanning radiometer uses 6 detectors that collect different bands of radiation wavelengths.\n\nThe first AVHRR was a 4-channel radiometer, first carried on TIROS-N (launched October 1978). This was subsequently improved to a 5-channel instrument (AVHRR/2) that was initially carried on NOAA-7 (launched June 1981). The latest instrument version is AVHRR/3, with 6 channels, first carried on NOAA-15 launched in May 1998." }, "relatedTo": { "ob_id": 32290, "uuid": "90a4f8cf26f24106a92d88db9f21a7e8", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative AVHRR-AM datasets", "abstract": "The ESA Cloud Climate Change Initiative AVHRR-AM datasets are based on intercalibrated measurements form the Advanced Very High Resolution Radiometer (AVHRR) sensors on-board the NOAA prime morning (AM) satellite NOAA-12,-15,-17, and the EUMETSAT Metop-A satellite." } }, { "ob_id": 12493, "platform": { "ob_id": 1831, "uuid": "4e8478da0c034af08d057e85dd4536be", "short_code": "plat", "title": "NOAA-17", "abstract": "NOAA polar orbiting satellite which was launched on June 24, 2002." }, "instrument": { "ob_id": 1817, "uuid": "eff26a2de66b4c6b9f71a15e875f52c5", "short_code": "instr", "title": "Advanced Very High Resolution Radiometer 3 (AVHRR/3)", "abstract": "The AVHRR is a radiation-detection imager that can be used for remotely determining cloud cover and the surface temperature. Note that the term surface can mean the surface of the Earth, the upper surfaces of clouds, or the surface of a body of water. This scanning radiometer uses 6 detectors that collect different bands of radiation wavelengths.\n\nThe first AVHRR was a 4-channel radiometer, first carried on TIROS-N (launched October 1978). This was subsequently improved to a 5-channel instrument (AVHRR/2) that was initially carried on NOAA-7 (launched June 1981). The latest instrument version is AVHRR/3, with 6 channels, first carried on NOAA-15 launched in May 1998." }, "relatedTo": { "ob_id": 32290, "uuid": "90a4f8cf26f24106a92d88db9f21a7e8", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative AVHRR-AM datasets", "abstract": "The ESA Cloud Climate Change Initiative AVHRR-AM datasets are based on intercalibrated measurements form the Advanced Very High Resolution Radiometer (AVHRR) sensors on-board the NOAA prime morning (AM) satellite NOAA-12,-15,-17, and the EUMETSAT Metop-A satellite." } }, { "ob_id": 12494, "platform": { "ob_id": 8207, "uuid": "3f2dbe69fe4c40ee9e1e8be87e15a1d5", "short_code": "plat", "title": "Metop-A", "abstract": "Metop-A, launched on 19 October 2006, represents the first in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS). Metop-A is Europe's first polar-orbiting meteorological satellite" }, "instrument": { "ob_id": 1817, "uuid": "eff26a2de66b4c6b9f71a15e875f52c5", "short_code": "instr", "title": "Advanced Very High Resolution Radiometer 3 (AVHRR/3)", "abstract": "The AVHRR is a radiation-detection imager that can be used for remotely determining cloud cover and the surface temperature. Note that the term surface can mean the surface of the Earth, the upper surfaces of clouds, or the surface of a body of water. This scanning radiometer uses 6 detectors that collect different bands of radiation wavelengths.\n\nThe first AVHRR was a 4-channel radiometer, first carried on TIROS-N (launched October 1978). This was subsequently improved to a 5-channel instrument (AVHRR/2) that was initially carried on NOAA-7 (launched June 1981). The latest instrument version is AVHRR/3, with 6 channels, first carried on NOAA-15 launched in May 1998." }, "relatedTo": { "ob_id": 32290, "uuid": "90a4f8cf26f24106a92d88db9f21a7e8", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative AVHRR-AM datasets", "abstract": "The ESA Cloud Climate Change Initiative AVHRR-AM datasets are based on intercalibrated measurements form the Advanced Very High Resolution Radiometer (AVHRR) sensors on-board the NOAA prime morning (AM) satellite NOAA-12,-15,-17, and the EUMETSAT Metop-A satellite." } } ] }, { "ob_id": 32291, "uuid": "350dffedb58a4592bb2ea1b374e53d37", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative AVHRR-PM datasets", "abstract": "The ESA Cloud Climate Change Initiative AVHRR-AM datasets are based on intercalibrated measurements form the Advanced Very High Resolution Radiometer (AVHRR) sensors on-board the NOAA prime afternoon (PM) satellite NOAA-7,-9,11,-14,-16,-18,-19 satellites.", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12496, "platform": { "ob_id": 27174, "uuid": "3dba7abe842a4f55b7d27d58cfa6b7ac", "short_code": "plat", "title": "NOAA-18", "abstract": "NOAA (National Oceanic and Atmospheric Administration) polar orbiting satellite which was launched on 20th May, 2005." }, "instrument": { "ob_id": 1817, "uuid": "eff26a2de66b4c6b9f71a15e875f52c5", "short_code": "instr", "title": "Advanced Very High Resolution Radiometer 3 (AVHRR/3)", "abstract": "The AVHRR is a radiation-detection imager that can be used for remotely determining cloud cover and the surface temperature. Note that the term surface can mean the surface of the Earth, the upper surfaces of clouds, or the surface of a body of water. This scanning radiometer uses 6 detectors that collect different bands of radiation wavelengths.\n\nThe first AVHRR was a 4-channel radiometer, first carried on TIROS-N (launched October 1978). This was subsequently improved to a 5-channel instrument (AVHRR/2) that was initially carried on NOAA-7 (launched June 1981). The latest instrument version is AVHRR/3, with 6 channels, first carried on NOAA-15 launched in May 1998." }, "relatedTo": { "ob_id": 32291, "uuid": "350dffedb58a4592bb2ea1b374e53d37", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative AVHRR-PM datasets", "abstract": "The ESA Cloud Climate Change Initiative AVHRR-AM datasets are based on intercalibrated measurements form the Advanced Very High Resolution Radiometer (AVHRR) sensors on-board the NOAA prime afternoon (PM) satellite NOAA-7,-9,11,-14,-16,-18,-19 satellites." } }, { "ob_id": 12497, "platform": { "ob_id": 1824, "uuid": "2a13c66bfad74b98b9cd4201c51de8c1", "short_code": "plat", "title": "NOAA-16", "abstract": "NOAA polar orbiting satellite which was launched on September 21, 2000" }, "instrument": { "ob_id": 1817, "uuid": "eff26a2de66b4c6b9f71a15e875f52c5", "short_code": "instr", "title": "Advanced Very High Resolution Radiometer 3 (AVHRR/3)", "abstract": "The AVHRR is a radiation-detection imager that can be used for remotely determining cloud cover and the surface temperature. Note that the term surface can mean the surface of the Earth, the upper surfaces of clouds, or the surface of a body of water. This scanning radiometer uses 6 detectors that collect different bands of radiation wavelengths.\n\nThe first AVHRR was a 4-channel radiometer, first carried on TIROS-N (launched October 1978). This was subsequently improved to a 5-channel instrument (AVHRR/2) that was initially carried on NOAA-7 (launched June 1981). The latest instrument version is AVHRR/3, with 6 channels, first carried on NOAA-15 launched in May 1998." }, "relatedTo": { "ob_id": 32291, "uuid": "350dffedb58a4592bb2ea1b374e53d37", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative AVHRR-PM datasets", "abstract": "The ESA Cloud Climate Change Initiative AVHRR-AM datasets are based on intercalibrated measurements form the Advanced Very High Resolution Radiometer (AVHRR) sensors on-board the NOAA prime afternoon (PM) satellite NOAA-7,-9,11,-14,-16,-18,-19 satellites." } }, { "ob_id": 12498, "platform": { "ob_id": 1809, "uuid": "e43da72c118e44ec811c395aa05a16be", "short_code": "plat", "title": "NOAA-14", "abstract": "NOAA polar orbiting satellite which operated during the period 30 December 1994 to Febraury 2001." }, "instrument": { "ob_id": 1817, "uuid": "eff26a2de66b4c6b9f71a15e875f52c5", "short_code": "instr", "title": "Advanced Very High Resolution Radiometer 3 (AVHRR/3)", "abstract": "The AVHRR is a radiation-detection imager that can be used for remotely determining cloud cover and the surface temperature. Note that the term surface can mean the surface of the Earth, the upper surfaces of clouds, or the surface of a body of water. This scanning radiometer uses 6 detectors that collect different bands of radiation wavelengths.\n\nThe first AVHRR was a 4-channel radiometer, first carried on TIROS-N (launched October 1978). This was subsequently improved to a 5-channel instrument (AVHRR/2) that was initially carried on NOAA-7 (launched June 1981). The latest instrument version is AVHRR/3, with 6 channels, first carried on NOAA-15 launched in May 1998." }, "relatedTo": { "ob_id": 32291, "uuid": "350dffedb58a4592bb2ea1b374e53d37", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative AVHRR-PM datasets", "abstract": "The ESA Cloud Climate Change Initiative AVHRR-AM datasets are based on intercalibrated measurements form the Advanced Very High Resolution Radiometer (AVHRR) sensors on-board the NOAA prime afternoon (PM) satellite NOAA-7,-9,11,-14,-16,-18,-19 satellites." } }, { "ob_id": 12499, "platform": { "ob_id": 1664, "uuid": "9298b7366f4e4f4ea637c8f854f88cf5", "short_code": "plat", "title": "NOAA-7", "abstract": "NASA polar-orbiting satellite which operated for the period 23rd June 1981 - 7th June 1986." }, "instrument": { "ob_id": 1802, "uuid": "adfffcff783c4b26ac9640ef4b141196", "short_code": "instr", "title": "Advanced Very High Resolution Radiometer 2 (AVHRR/2)", "abstract": "The AVHRR is a radiation-detection imager that can be used for remotely determining cloud cover and the surface temperature. Note that the term surface can mean the surface of the Earth, the upper surfaces of clouds, or the surface of a body of water. This scanning radiometer uses 6 detectors that collect different bands of radiation wavelengths.\n\nThe first AVHRR was a 4-channel radiometer, first carried on TIROS-N (launched October 1978). This was subsequently improved to a 5-channel instrument (AVHRR/2) that was initially carried on NOAA-7 (launched June 1981). The latest instrument version is AVHRR/3, with 6 channels, first carried on NOAA-15 launched in May 1998." }, "relatedTo": { "ob_id": 32291, "uuid": "350dffedb58a4592bb2ea1b374e53d37", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative AVHRR-PM datasets", "abstract": "The ESA Cloud Climate Change Initiative AVHRR-AM datasets are based on intercalibrated measurements form the Advanced Very High Resolution Radiometer (AVHRR) sensors on-board the NOAA prime afternoon (PM) satellite NOAA-7,-9,11,-14,-16,-18,-19 satellites." } }, { "ob_id": 12500, "platform": { "ob_id": 1679, "uuid": "25e813e1539d46aeaf320dc3e4f06b8f", "short_code": "plat", "title": "NOAA-9", "abstract": "NASA polar-orbiting satellite which operated for the period december 1984 to August 1993." }, "instrument": { "ob_id": 1802, "uuid": "adfffcff783c4b26ac9640ef4b141196", "short_code": "instr", "title": "Advanced Very High Resolution Radiometer 2 (AVHRR/2)", "abstract": "The AVHRR is a radiation-detection imager that can be used for remotely determining cloud cover and the surface temperature. Note that the term surface can mean the surface of the Earth, the upper surfaces of clouds, or the surface of a body of water. This scanning radiometer uses 6 detectors that collect different bands of radiation wavelengths.\n\nThe first AVHRR was a 4-channel radiometer, first carried on TIROS-N (launched October 1978). This was subsequently improved to a 5-channel instrument (AVHRR/2) that was initially carried on NOAA-7 (launched June 1981). The latest instrument version is AVHRR/3, with 6 channels, first carried on NOAA-15 launched in May 1998." }, "relatedTo": { "ob_id": 32291, "uuid": "350dffedb58a4592bb2ea1b374e53d37", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative AVHRR-PM datasets", "abstract": "The ESA Cloud Climate Change Initiative AVHRR-AM datasets are based on intercalibrated measurements form the Advanced Very High Resolution Radiometer (AVHRR) sensors on-board the NOAA prime afternoon (PM) satellite NOAA-7,-9,11,-14,-16,-18,-19 satellites." } }, { "ob_id": 12501, "platform": { "ob_id": 1693, "uuid": "922c7e6cc7d04fa78ca9b30cd4d646c8", "short_code": "plat", "title": "NOAA-11", "abstract": "NASA polar orbiting satellite which operated during the period 24 Spetember 1988 to March 1995." }, "instrument": { "ob_id": 1802, "uuid": "adfffcff783c4b26ac9640ef4b141196", "short_code": "instr", "title": "Advanced Very High Resolution Radiometer 2 (AVHRR/2)", "abstract": "The AVHRR is a radiation-detection imager that can be used for remotely determining cloud cover and the surface temperature. Note that the term surface can mean the surface of the Earth, the upper surfaces of clouds, or the surface of a body of water. This scanning radiometer uses 6 detectors that collect different bands of radiation wavelengths.\n\nThe first AVHRR was a 4-channel radiometer, first carried on TIROS-N (launched October 1978). This was subsequently improved to a 5-channel instrument (AVHRR/2) that was initially carried on NOAA-7 (launched June 1981). The latest instrument version is AVHRR/3, with 6 channels, first carried on NOAA-15 launched in May 1998." }, "relatedTo": { "ob_id": 32291, "uuid": "350dffedb58a4592bb2ea1b374e53d37", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative AVHRR-PM datasets", "abstract": "The ESA Cloud Climate Change Initiative AVHRR-AM datasets are based on intercalibrated measurements form the Advanced Very High Resolution Radiometer (AVHRR) sensors on-board the NOAA prime afternoon (PM) satellite NOAA-7,-9,11,-14,-16,-18,-19 satellites." } }, { "ob_id": 12502, "platform": { "ob_id": 27175, "uuid": "c6470e63d7f84f20b9c765be3d0b9352", "short_code": "plat", "title": "NOAA-19", "abstract": "NOAA (National Oceanic and Atmospheric Administration) polar orbiting satellite which was launched on 6th February 2009" }, "instrument": { "ob_id": 1817, "uuid": "eff26a2de66b4c6b9f71a15e875f52c5", "short_code": "instr", "title": "Advanced Very High Resolution Radiometer 3 (AVHRR/3)", "abstract": "The AVHRR is a radiation-detection imager that can be used for remotely determining cloud cover and the surface temperature. Note that the term surface can mean the surface of the Earth, the upper surfaces of clouds, or the surface of a body of water. This scanning radiometer uses 6 detectors that collect different bands of radiation wavelengths.\n\nThe first AVHRR was a 4-channel radiometer, first carried on TIROS-N (launched October 1978). This was subsequently improved to a 5-channel instrument (AVHRR/2) that was initially carried on NOAA-7 (launched June 1981). The latest instrument version is AVHRR/3, with 6 channels, first carried on NOAA-15 launched in May 1998." }, "relatedTo": { "ob_id": 32291, "uuid": "350dffedb58a4592bb2ea1b374e53d37", "short_code": "acq", "title": "Acquisition for the ESA Cloud Climate Change Initiative AVHRR-PM datasets", "abstract": "The ESA Cloud Climate Change Initiative AVHRR-AM datasets are based on intercalibrated measurements form the Advanced Very High Resolution Radiometer (AVHRR) sensors on-board the NOAA prime afternoon (PM) satellite NOAA-7,-9,11,-14,-16,-18,-19 satellites." } } ] }, { "ob_id": 32301, "uuid": "9bd10428b3374f4497416b651ea9e61c", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v06.1", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments.", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 7807, "uuid": "a27cd0df0a124f2ca5873877e21f637e", "short_code": "mpop", "title": "Mobile Platform Operation for: ERS-1", "abstract": "Mobile Platform Operation related to the: ERS-1" }, { "ob_id": 7814, "uuid": "ae416a28a96049e7bf33ea668c187852", "short_code": "mpop", "title": "Mobile Platform Operation for: ERS-2", "abstract": "Mobile Platform Operation related to the: ERS-2" }, { "ob_id": 8209, "uuid": "f0f061d64cca41c3a4221b713fd6b1be", "short_code": "mpop", "title": "Mobile Platform Operation for: Metop-A", "abstract": "Mobile Platform Operation related to the: Metop-A" }, { "ob_id": 8301, "uuid": "d1d4ffcf747d4e95a3614aa20f1855da", "short_code": "mpop", "title": "Mobile Platform Operation for: Metop-B", "abstract": "Mobile Platform Operation related to the: Metop-B" } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12505, "platform": { "ob_id": 8299, "uuid": "84a6355ac58249cc8c636e77a243c86a", "short_code": "plat", "title": "Metop-B", "abstract": "Metop-B, launched on the 17th September 2012, is the second in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS)." }, "instrument": { "ob_id": 27121, "uuid": "ca133e0771514003a9e7c2462c1b363c", "short_code": "instr", "title": "ASCAT", "abstract": "ASCAT (Advanced Scatterometer) is a C Band (2.55 GHz) Scatterometer flown on the Metop series of satellites. It measures the sea surface wind vecotr and large-scale soil moisture." }, "relatedTo": { "ob_id": 32301, "uuid": "9bd10428b3374f4497416b651ea9e61c", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v06.1", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments." } }, { "ob_id": 12506, "platform": { "ob_id": 8207, "uuid": "3f2dbe69fe4c40ee9e1e8be87e15a1d5", "short_code": "plat", "title": "Metop-A", "abstract": "Metop-A, launched on 19 October 2006, represents the first in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS). Metop-A is Europe's first polar-orbiting meteorological satellite" }, "instrument": { "ob_id": 27121, "uuid": "ca133e0771514003a9e7c2462c1b363c", "short_code": "instr", "title": "ASCAT", "abstract": "ASCAT (Advanced Scatterometer) is a C Band (2.55 GHz) Scatterometer flown on the Metop series of satellites. It measures the sea surface wind vecotr and large-scale soil moisture." }, "relatedTo": { "ob_id": 32301, "uuid": "9bd10428b3374f4497416b651ea9e61c", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v06.1", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments." } }, { "ob_id": 12503, "platform": { "ob_id": 7813, "uuid": "8ee876e1ea644ed7a81d4e3536133fa0", "short_code": "plat", "title": "European Remote Sensing satellite 2 - ERS-2", "abstract": "ESA's two European Remote Sensing (ERS) satellites, ERS-1 and –2, were launched into the same orbit in 1991 and 1995 respectively. Their payloads included a synthetic aperture imaging radar, radar altimeter and instruments to measure ocean surface temperature and wind fields.\r\n\r\nERS-2 added an additional sensor for atmospheric ozone monitoring. The two satellites acquired a combined data set extending over two decades.\r\n\r\nThe ERS-2 satellite was retired on 05 September 2011." }, "instrument": { "ob_id": 27122, "uuid": "7b488736a173477689480990d5b38aa9", "short_code": "instr", "title": "AMI-SCAT", "abstract": "AMI-SCAT (Active Microwave Instrument - Scatterometer) is a C-band (5.3 GHz) scatterometer flying on the ERS-1 and ERS-2 satellites. It measures the sea surface wind vector and large-scale soil moisture." }, "relatedTo": { "ob_id": 32301, "uuid": "9bd10428b3374f4497416b651ea9e61c", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v06.1", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments." } }, { "ob_id": 12504, "platform": { "ob_id": 7805, "uuid": "d21630e98aa74a4f8406743b74e5d076", "short_code": "plat", "title": "ERS-1", "abstract": "The European Remote Sensing satellite 1 (ERS1) was launched on 17th July 1991 and was the first flight of the RSA ERS program. The payload included the ATSR, AMU-SAR , AMI-SCAT, LRR PRARE and RA instruments. End of mission for ERS1 was 10th March 2000." }, "instrument": { "ob_id": 27122, "uuid": "7b488736a173477689480990d5b38aa9", "short_code": "instr", "title": "AMI-SCAT", "abstract": "AMI-SCAT (Active Microwave Instrument - Scatterometer) is a C-band (5.3 GHz) scatterometer flying on the ERS-1 and ERS-2 satellites. It measures the sea surface wind vector and large-scale soil moisture." }, "relatedTo": { "ob_id": 32301, "uuid": "9bd10428b3374f4497416b651ea9e61c", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Active product, v06.1", "abstract": "The ESA Climate Change Initiative Active product has been derived from data from the AMI-WS and ASCAT satellite instruments." } } ] }, { "ob_id": 32302, "uuid": "caf40bff974144e08c815200db700f48", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v06.1", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS), SMAP, FY-3B, and GPM satellite instruments.", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 460, "uuid": "bea2c6443d2f4f81a2701f09cb4e6f5c", "short_code": "mpop", "title": "Mobile Platform Operation for: NIMBUS 7 Satellite", "abstract": "Mobile Platform Operation related to the: NIMBUS 7 Satellite" }, { "ob_id": 2631, "uuid": "4647e36325d544eca3db5d8795c216c6", "short_code": "mpop", "title": "Mobile Platform Operation for: Defense Meteorological Satellite Program (DMSP) Satellites", "abstract": "Mobile Platform Operation related to the: Defense Meteorological Satellite Program (DMSP) Satellites" }, { "ob_id": 10907, "uuid": "1be652a219874193976dff38a64fc180", "short_code": "mpop", "title": "Aqua Satellite orbit details", "abstract": "NASA's AQUA (EOS-PM1) is a sun-synchronous, polar orbiting satellite in an afternoon orbit, with equator crossing times of approximately 13:30 and 01:30. It forms part of the A-train, a collection of satellites orbiting close together along the same orbital track" }, { "ob_id": 27132, "uuid": "6c74884699f541ff8a1edb33933ddada", "short_code": "mpop", "title": "Coriolis Satellite Orbit Details", "abstract": "The Coriolis Satellite is flown by NASA and the US Department of Defence and is in a Sunsynchronous orbit with an 06.10 descending equator crossing time." }, { "ob_id": 27133, "uuid": "c15fb49dfbf24bdc81acb5ae16df1b1d", "short_code": "mpop", "title": "SMOS satellite orbit details", "abstract": "The SMOS satellite is operated by ESA and is in a sunscynchronous orbit with a 06:00 ascending equator crossing time." }, { "ob_id": 27137, "uuid": "f6550c6efe0c4a9baaf3c5d07627b2ed", "short_code": "mpop", "title": "GCOM-W satellite orbit details", "abstract": "The GCOM-W (Global Change Observation Mission for Water) is a JAXA satellite in a sunsynchronous orbit with a 13.30 ascending equator crossing time." }, { "ob_id": 27138, "uuid": "44f2493522254d2696575ce3acb6146c", "short_code": "mpop", "title": "TRMM satellite orbit details", "abstract": "The TRMM (Tropical Rainfall Measuring Mission) is a NASA, JAXA satellite mission. It is in a drifting orbit with an inclination of 35 degrees and altitude of 402 km." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12515, "platform": { "ob_id": 32304, "uuid": "4aae55216d5f4c25a23408480cac8f18", "short_code": "plat", "title": "FY-3B", "abstract": "Feng-Yun -3B (FY-3B) is a Chinese satellite flying between 2010-2021. It is the second in the FY-3 series of satellites, with a primary mission for operational meteorology." }, "instrument": { "ob_id": 32315, "uuid": "bef9923c589d4aa78826a8ab170ac025", "short_code": "instr", "title": "VIRR (FY-3)", "abstract": "The Visible and Infra-Red Radiometer (VIRR) is one of the instruments on the Chinese Feng-Yun -3 (FY-3) series of satellites." }, "relatedTo": { "ob_id": 32302, "uuid": "caf40bff974144e08c815200db700f48", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v06.1", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS), SMAP, FY-3B, and GPM satellite instruments." } }, { "ob_id": 12507, "platform": { "ob_id": 29941, "uuid": "2b126b39dbb64c0681f12b68f2308fee", "short_code": "plat", "title": "SMAP", "abstract": "The Soil Moisture Active-Passive (SMAP) satelliteis a NASA satellite launched in 2015." }, "instrument": { "ob_id": 29938, "uuid": "e050ad22e3b943f9a5f1563a1e6fb82c", "short_code": "instr", "title": "SMAP", "abstract": "The Soil Moisture Active Passive instrument is a microwave radiometer flown on the NASA SMAP satellite." }, "relatedTo": { "ob_id": 32302, "uuid": "caf40bff974144e08c815200db700f48", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v06.1", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS), SMAP, FY-3B, and GPM satellite instruments." } }, { "ob_id": 12508, "platform": { "ob_id": 27128, "uuid": "9c6e8c73f539446ba7a8adef871492a7", "short_code": "plat", "title": "SMOS", "abstract": "The SMOS (Soil Moisture and Ocean Salinity) satellite was launched on Novermber 2009, with the primary mission to monitor ocean salinity and soil moisture." }, "instrument": { "ob_id": 27124, "uuid": "9b4be0d67030450ca8aebf37cf39500c", "short_code": "instr", "title": "MIRAS", "abstract": "MIRAS (Microwave Imaging Radiometer using Aperture Synthesis) is an European Space Agency instrument flown on the SMOS (Soil Moisture and Ocean Salinity) Satellite. It measures Ocean Salinity and Soil Moisture." }, "relatedTo": { "ob_id": 32302, "uuid": "caf40bff974144e08c815200db700f48", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v06.1", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS), SMAP, FY-3B, and GPM satellite instruments." } }, { "ob_id": 12509, "platform": { "ob_id": 27130, "uuid": "526c6fb02e094d049d367aaa4f79e8d1", "short_code": "plat", "title": "Coriolis", "abstract": "The Coriolis satellite is flown by NASA and the US Department of Defence, with a primary mission to provide observations of the sea-surface wind. It carries two instruments: WindSat and SMEI (Solar Mass Ejection Imager)" }, "instrument": { "ob_id": 27125, "uuid": "10f4aca379f84e0cae56392a85604469", "short_code": "instr", "title": "WindSat", "abstract": "WindSat is a passive microwave radiometer flown on the Coriolis Satellite by the US Department of Defence since 2003." }, "relatedTo": { "ob_id": 32302, "uuid": "caf40bff974144e08c815200db700f48", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v06.1", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS), SMAP, FY-3B, and GPM satellite instruments." } }, { "ob_id": 12510, "platform": { "ob_id": 25273, "uuid": "f10d619f7b9f4dbab792dcc1ab9dbb68", "short_code": "plat", "title": "GCOM-W (Global Change Observation Mission for Water)", "abstract": "The Global Change Observation Mission for Water (GCOM-W) is a series of three satellites flown by the Japanese Space Agency (JAXA), addressing multi-purpose MW imagery for ocean, land and precipitation. It is part of their Global Change Observation Mission (GCOM).\r\nThe satellites exploit sun-synchronous orbits around 13:30, coordinated with that of POES satellites, Suomi-NPP and JPSS." }, "instrument": { "ob_id": 25272, "uuid": "a6002da7c0954ce0aa146c1b24877a0a", "short_code": "instr", "title": "AMSR-2", "abstract": "Advanced Microwave Scanning Radiometer -2, flying on the Global Change Observation Mission (GCOM) series of satellites flown by JAXA" }, "relatedTo": { "ob_id": 32302, "uuid": "caf40bff974144e08c815200db700f48", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v06.1", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS), SMAP, FY-3B, and GPM satellite instruments." } }, { "ob_id": 12511, "platform": { "ob_id": 10906, "uuid": "5a1076bffc8c4c5d8a2ff3a4cfb29846", "short_code": "plat", "title": "Aqua Satellite, part of the Earth Observation System Afternoon Constellation (EOS-PM)", "abstract": "Aqua, launched on 4th April 2002, is a polar-orbiting satellite within the Afternoon Constellation (A-Train) that have equator crossings around 13:30 and 01:30 under NASA's Earth Obseration System (EOS). The satellite carries Atmospheric Infrared Sounder (AIRS), Advanced Microwave Sounding Unit (AMSU-A), Humidity Sounder for Brazil (HSB), Advanced Microwave Scanning Radiometer for EOS (AMSR-E), Moderate-Resolution Imaging Spectroradiometer (MODIS) and Clouds and the Earth's Radiant Energy System (CERES), and these collect data on the Earth's atmospheric conditions, snow and ice, sea surface temperature and ocean productivity, and soil moisture. Aqua was the first member launched of a group of satellites termed the Afternoon Constellation, or sometimes the A-Train. " }, "instrument": { "ob_id": 14485, "uuid": "77dd26fc341a440b85a98fe95b1976f8", "short_code": "instr", "title": "AMSR-E", "abstract": "Advanced Microwave Scanning Radiometer for EOS" }, "relatedTo": { "ob_id": 32302, "uuid": "caf40bff974144e08c815200db700f48", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v06.1", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS), SMAP, FY-3B, and GPM satellite instruments." } }, { "ob_id": 12512, "platform": { "ob_id": 27135, "uuid": "8afe985a2f3f4b15aaa52df6119c0f27", "short_code": "plat", "title": "TRMM", "abstract": "The Tropical Rainfall Measuring Mission (TRMM) is a NASA and JAXA satellite that flew between 1997 and 2015. It's primary mission was to measure precipitation." }, "instrument": { "ob_id": 27126, "uuid": "9173171ba44845e9a873e21b4dee19e2", "short_code": "instr", "title": "TMI", "abstract": "TMI (TRMM Microwave Imager) is a multi-purpose microwave imager flying on the TRMM (Tropical Rainfall Measuring Mission)." }, "relatedTo": { "ob_id": 32302, "uuid": "caf40bff974144e08c815200db700f48", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v06.1", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS), SMAP, FY-3B, and GPM satellite instruments." } }, { "ob_id": 12513, "platform": { "ob_id": 2629, "uuid": "9f1b0a2380cc47919b201880e0fee6de", "short_code": "plat", "title": "Defense Meteorological Satellite Program (DMSP) Satellites", "abstract": "DMSP satellites are used for strategic and tactical weather prediction to aid the U.S. military in planning operations at sea, on land and in the air. Equipped with a sophisticated sensor suite that can image visible and infrared cloud cover and measure precipitation, surface temperature, and soil moisture, the satellite collects specialized global meteorological, oceanographic, and solar-geophysical information in all weather conditions. The DMSP constellation comprises two spacecraft in near-polar orbits, C3 (command, control and communications), user terminals and weather centers." }, "instrument": { "ob_id": 2630, "uuid": "54f897597ec04c09b01095eb05c7419e", "short_code": "instr", "title": "Special Sensor Microwave / Imager (SSM/I)", "abstract": "The SSM/I is a seven-channel, four frequency, linearly-polarized, passive microwave radiometric system which measures atmospheric, ocean and terrain microwave brightness temperatures at 19.35, 22.235, 37.0 and 85.5 GHz. The data are used to obtain synoptic maps of critical atmospheric, oceanographic and selected land parameters on a global scale." }, "relatedTo": { "ob_id": 32302, "uuid": "caf40bff974144e08c815200db700f48", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v06.1", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS), SMAP, FY-3B, and GPM satellite instruments." } }, { "ob_id": 12514, "platform": { "ob_id": 458, "uuid": "b6d87ac1455348cd97a4386b38995dbb", "short_code": "plat", "title": "NIMBUS 7 Satellite", "abstract": "The NASA Nimbus 7 research-and-development polar-orbiting satellite served as a stabilized, earth-oriented platform for the testing of advanced systems for sensing and collecting data in the pollution, oceanographic and meteorological disciplines. It was launched on October 24, 1978." }, "instrument": { "ob_id": 2636, "uuid": "1578228cc3cf4b9fba0b88c61b58800b", "short_code": "instr", "title": "Scanning Multichannel Microwave Radiometer (SMMR)", "abstract": "The Scanning Multichannel Microwave Radiometer operated on NASA's Nimbus-7 satellite for more than eight years, from 26 October 1978 to 20 August 1987, transmitting data every other day. Intended to obtain ocean circulation parameters such as sea surface temperatures, low altitude winds, water vapor and cloud liquid water content on an all-weather basis, the SMMR is a ten channel instrument capable of receiving both horizontally and vertically polarized radiation. A parabolic antenna 79 cm in diameter reflected microwave emissions into a five-frequency feed horn. The antenna beam maintained a constant nadir angle of 42 degrees, resulting in an incidence angle of 50.3 degrees at Earth's surface. The antenna was forward viewing and rotated equally +/- 25 degrees about the satellite subtrack. The 50 degree scan provided a 780 km swath of the Earth's surface. Scan period was 4.096 seconds." }, "relatedTo": { "ob_id": 32302, "uuid": "caf40bff974144e08c815200db700f48", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v06.1", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS), SMAP, FY-3B, and GPM satellite instruments." } }, { "ob_id": 12516, "platform": { "ob_id": 32306, "uuid": "0cc9d1b2d73b4fe3983cbb95827b2581", "short_code": "plat", "title": "GPM - Core Observatory", "abstract": "The Global Precipitation Mission (GPM) - Core Observatory is an operational satellite flown by NASA and JAXA, and forms the main element of the Global Precipitation Measurement mission. It carries two instruments: DPR (Dual-frequency Precipitation Radar), and GMI (GPM Microwave Imager)" }, "instrument": { "ob_id": 32305, "uuid": "7db99f9f3e5d4e63bf748dc395124886", "short_code": "instr", "title": "GMI (core)", "abstract": "The GPM Microwave Imager (GPI) is a multipurpose imager flown on the Global Precipitation Mission (GPM) Core Observatory by NASA" }, "relatedTo": { "ob_id": 32302, "uuid": "caf40bff974144e08c815200db700f48", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Passive product, v06.1", "abstract": "The ESA Climate Change Initiative Passive product has been derived from data from the SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2 , MIRAS (SMOS), SMAP, FY-3B, and GPM satellite instruments." } } ] }, { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 460, "uuid": "bea2c6443d2f4f81a2701f09cb4e6f5c", "short_code": "mpop", "title": "Mobile Platform Operation for: NIMBUS 7 Satellite", "abstract": "Mobile Platform Operation related to the: NIMBUS 7 Satellite" }, { "ob_id": 2631, "uuid": "4647e36325d544eca3db5d8795c216c6", "short_code": "mpop", "title": "Mobile Platform Operation for: Defense Meteorological Satellite Program (DMSP) Satellites", "abstract": "Mobile Platform Operation related to the: Defense Meteorological Satellite Program (DMSP) Satellites" }, { "ob_id": 7807, "uuid": "a27cd0df0a124f2ca5873877e21f637e", "short_code": "mpop", "title": "Mobile Platform Operation for: ERS-1", "abstract": "Mobile Platform Operation related to the: ERS-1" }, { "ob_id": 7814, "uuid": "ae416a28a96049e7bf33ea668c187852", "short_code": "mpop", "title": "Mobile Platform Operation for: ERS-2", "abstract": "Mobile Platform Operation related to the: ERS-2" }, { "ob_id": 8209, "uuid": "f0f061d64cca41c3a4221b713fd6b1be", "short_code": "mpop", "title": "Mobile Platform Operation for: Metop-A", "abstract": "Mobile Platform Operation related to the: Metop-A" }, { "ob_id": 8301, "uuid": "d1d4ffcf747d4e95a3614aa20f1855da", "short_code": "mpop", "title": "Mobile Platform Operation for: Metop-B", "abstract": "Mobile Platform Operation related to the: Metop-B" }, { "ob_id": 10907, "uuid": "1be652a219874193976dff38a64fc180", "short_code": "mpop", "title": "Aqua Satellite orbit details", "abstract": "NASA's AQUA (EOS-PM1) is a sun-synchronous, polar orbiting satellite in an afternoon orbit, with equator crossing times of approximately 13:30 and 01:30. It forms part of the A-train, a collection of satellites orbiting close together along the same orbital track" }, { "ob_id": 27132, "uuid": "6c74884699f541ff8a1edb33933ddada", "short_code": "mpop", "title": "Coriolis Satellite Orbit Details", "abstract": "The Coriolis Satellite is flown by NASA and the US Department of Defence and is in a Sunsynchronous orbit with an 06.10 descending equator crossing time." }, { "ob_id": 27133, "uuid": "c15fb49dfbf24bdc81acb5ae16df1b1d", "short_code": "mpop", "title": "SMOS satellite orbit details", "abstract": "The SMOS satellite is operated by ESA and is in a sunscynchronous orbit with a 06:00 ascending equator crossing time." }, { "ob_id": 27137, "uuid": "f6550c6efe0c4a9baaf3c5d07627b2ed", "short_code": "mpop", "title": "GCOM-W satellite orbit details", "abstract": "The GCOM-W (Global Change Observation Mission for Water) is a JAXA satellite in a sunsynchronous orbit with a 13.30 ascending equator crossing time." }, { "ob_id": 27138, "uuid": "44f2493522254d2696575ce3acb6146c", "short_code": "mpop", "title": "TRMM satellite orbit details", "abstract": "The TRMM (Tropical Rainfall Measuring Mission) is a NASA, JAXA satellite mission. It is in a drifting orbit with an inclination of 35 degrees and altitude of 402 km." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12529, "platform": { "ob_id": 32304, "uuid": "4aae55216d5f4c25a23408480cac8f18", "short_code": "plat", "title": "FY-3B", "abstract": "Feng-Yun -3B (FY-3B) is a Chinese satellite flying between 2010-2021. It is the second in the FY-3 series of satellites, with a primary mission for operational meteorology." }, "instrument": { "ob_id": 32315, "uuid": "bef9923c589d4aa78826a8ab170ac025", "short_code": "instr", "title": "VIRR (FY-3)", "abstract": "The Visible and Infra-Red Radiometer (VIRR) is one of the instruments on the Chinese Feng-Yun -3 (FY-3) series of satellites." }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } }, { "ob_id": 12517, "platform": { "ob_id": 29941, "uuid": "2b126b39dbb64c0681f12b68f2308fee", "short_code": "plat", "title": "SMAP", "abstract": "The Soil Moisture Active-Passive (SMAP) satelliteis a NASA satellite launched in 2015." }, "instrument": { "ob_id": 29938, "uuid": "e050ad22e3b943f9a5f1563a1e6fb82c", "short_code": "instr", "title": "SMAP", "abstract": "The Soil Moisture Active Passive instrument is a microwave radiometer flown on the NASA SMAP satellite." }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } }, { "ob_id": 12518, "platform": { "ob_id": 7813, "uuid": "8ee876e1ea644ed7a81d4e3536133fa0", "short_code": "plat", "title": "European Remote Sensing satellite 2 - ERS-2", "abstract": "ESA's two European Remote Sensing (ERS) satellites, ERS-1 and –2, were launched into the same orbit in 1991 and 1995 respectively. Their payloads included a synthetic aperture imaging radar, radar altimeter and instruments to measure ocean surface temperature and wind fields.\r\n\r\nERS-2 added an additional sensor for atmospheric ozone monitoring. The two satellites acquired a combined data set extending over two decades.\r\n\r\nThe ERS-2 satellite was retired on 05 September 2011." }, "instrument": { "ob_id": 27122, "uuid": "7b488736a173477689480990d5b38aa9", "short_code": "instr", "title": "AMI-SCAT", "abstract": "AMI-SCAT (Active Microwave Instrument - Scatterometer) is a C-band (5.3 GHz) scatterometer flying on the ERS-1 and ERS-2 satellites. It measures the sea surface wind vector and large-scale soil moisture." }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } }, { "ob_id": 12519, "platform": { "ob_id": 7805, "uuid": "d21630e98aa74a4f8406743b74e5d076", "short_code": "plat", "title": "ERS-1", "abstract": "The European Remote Sensing satellite 1 (ERS1) was launched on 17th July 1991 and was the first flight of the RSA ERS program. The payload included the ATSR, AMU-SAR , AMI-SCAT, LRR PRARE and RA instruments. End of mission for ERS1 was 10th March 2000." }, "instrument": { "ob_id": 27122, "uuid": "7b488736a173477689480990d5b38aa9", "short_code": "instr", "title": "AMI-SCAT", "abstract": "AMI-SCAT (Active Microwave Instrument - Scatterometer) is a C-band (5.3 GHz) scatterometer flying on the ERS-1 and ERS-2 satellites. It measures the sea surface wind vector and large-scale soil moisture." }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } }, { "ob_id": 12520, "platform": { "ob_id": 8299, "uuid": "84a6355ac58249cc8c636e77a243c86a", "short_code": "plat", "title": "Metop-B", "abstract": "Metop-B, launched on the 17th September 2012, is the second in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS)." }, "instrument": { "ob_id": 27121, "uuid": "ca133e0771514003a9e7c2462c1b363c", "short_code": "instr", "title": "ASCAT", "abstract": "ASCAT (Advanced Scatterometer) is a C Band (2.55 GHz) Scatterometer flown on the Metop series of satellites. It measures the sea surface wind vecotr and large-scale soil moisture." }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } }, { "ob_id": 12521, "platform": { "ob_id": 8207, "uuid": "3f2dbe69fe4c40ee9e1e8be87e15a1d5", "short_code": "plat", "title": "Metop-A", "abstract": "Metop-A, launched on 19 October 2006, represents the first in a series of three satellites forming the space segment of the EUMETSAT Polar System (EPS). Metop-A is Europe's first polar-orbiting meteorological satellite" }, "instrument": { "ob_id": 27121, "uuid": "ca133e0771514003a9e7c2462c1b363c", "short_code": "instr", "title": "ASCAT", "abstract": "ASCAT (Advanced Scatterometer) is a C Band (2.55 GHz) Scatterometer flown on the Metop series of satellites. It measures the sea surface wind vecotr and large-scale soil moisture." }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } }, { "ob_id": 12522, "platform": { "ob_id": 458, "uuid": "b6d87ac1455348cd97a4386b38995dbb", "short_code": "plat", "title": "NIMBUS 7 Satellite", "abstract": "The NASA Nimbus 7 research-and-development polar-orbiting satellite served as a stabilized, earth-oriented platform for the testing of advanced systems for sensing and collecting data in the pollution, oceanographic and meteorological disciplines. It was launched on October 24, 1978." }, "instrument": { "ob_id": 2636, "uuid": "1578228cc3cf4b9fba0b88c61b58800b", "short_code": "instr", "title": "Scanning Multichannel Microwave Radiometer (SMMR)", "abstract": "The Scanning Multichannel Microwave Radiometer operated on NASA's Nimbus-7 satellite for more than eight years, from 26 October 1978 to 20 August 1987, transmitting data every other day. Intended to obtain ocean circulation parameters such as sea surface temperatures, low altitude winds, water vapor and cloud liquid water content on an all-weather basis, the SMMR is a ten channel instrument capable of receiving both horizontally and vertically polarized radiation. A parabolic antenna 79 cm in diameter reflected microwave emissions into a five-frequency feed horn. The antenna beam maintained a constant nadir angle of 42 degrees, resulting in an incidence angle of 50.3 degrees at Earth's surface. The antenna was forward viewing and rotated equally +/- 25 degrees about the satellite subtrack. The 50 degree scan provided a 780 km swath of the Earth's surface. Scan period was 4.096 seconds." }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } }, { "ob_id": 12523, "platform": { "ob_id": 2629, "uuid": "9f1b0a2380cc47919b201880e0fee6de", "short_code": "plat", "title": "Defense Meteorological Satellite Program (DMSP) Satellites", "abstract": "DMSP satellites are used for strategic and tactical weather prediction to aid the U.S. military in planning operations at sea, on land and in the air. Equipped with a sophisticated sensor suite that can image visible and infrared cloud cover and measure precipitation, surface temperature, and soil moisture, the satellite collects specialized global meteorological, oceanographic, and solar-geophysical information in all weather conditions. The DMSP constellation comprises two spacecraft in near-polar orbits, C3 (command, control and communications), user terminals and weather centers." }, "instrument": { "ob_id": 2630, "uuid": "54f897597ec04c09b01095eb05c7419e", "short_code": "instr", "title": "Special Sensor Microwave / Imager (SSM/I)", "abstract": "The SSM/I is a seven-channel, four frequency, linearly-polarized, passive microwave radiometric system which measures atmospheric, ocean and terrain microwave brightness temperatures at 19.35, 22.235, 37.0 and 85.5 GHz. The data are used to obtain synoptic maps of critical atmospheric, oceanographic and selected land parameters on a global scale." }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } }, { "ob_id": 12524, "platform": { "ob_id": 27135, "uuid": "8afe985a2f3f4b15aaa52df6119c0f27", "short_code": "plat", "title": "TRMM", "abstract": "The Tropical Rainfall Measuring Mission (TRMM) is a NASA and JAXA satellite that flew between 1997 and 2015. It's primary mission was to measure precipitation." }, "instrument": { "ob_id": 27126, "uuid": "9173171ba44845e9a873e21b4dee19e2", "short_code": "instr", "title": "TMI", "abstract": "TMI (TRMM Microwave Imager) is a multi-purpose microwave imager flying on the TRMM (Tropical Rainfall Measuring Mission)." }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } }, { "ob_id": 12525, "platform": { "ob_id": 10906, "uuid": "5a1076bffc8c4c5d8a2ff3a4cfb29846", "short_code": "plat", "title": "Aqua Satellite, part of the Earth Observation System Afternoon Constellation (EOS-PM)", "abstract": "Aqua, launched on 4th April 2002, is a polar-orbiting satellite within the Afternoon Constellation (A-Train) that have equator crossings around 13:30 and 01:30 under NASA's Earth Obseration System (EOS). The satellite carries Atmospheric Infrared Sounder (AIRS), Advanced Microwave Sounding Unit (AMSU-A), Humidity Sounder for Brazil (HSB), Advanced Microwave Scanning Radiometer for EOS (AMSR-E), Moderate-Resolution Imaging Spectroradiometer (MODIS) and Clouds and the Earth's Radiant Energy System (CERES), and these collect data on the Earth's atmospheric conditions, snow and ice, sea surface temperature and ocean productivity, and soil moisture. Aqua was the first member launched of a group of satellites termed the Afternoon Constellation, or sometimes the A-Train. " }, "instrument": { "ob_id": 14485, "uuid": "77dd26fc341a440b85a98fe95b1976f8", "short_code": "instr", "title": "AMSR-E", "abstract": "Advanced Microwave Scanning Radiometer for EOS" }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } }, { "ob_id": 12526, "platform": { "ob_id": 25273, "uuid": "f10d619f7b9f4dbab792dcc1ab9dbb68", "short_code": "plat", "title": "GCOM-W (Global Change Observation Mission for Water)", "abstract": "The Global Change Observation Mission for Water (GCOM-W) is a series of three satellites flown by the Japanese Space Agency (JAXA), addressing multi-purpose MW imagery for ocean, land and precipitation. It is part of their Global Change Observation Mission (GCOM).\r\nThe satellites exploit sun-synchronous orbits around 13:30, coordinated with that of POES satellites, Suomi-NPP and JPSS." }, "instrument": { "ob_id": 25272, "uuid": "a6002da7c0954ce0aa146c1b24877a0a", "short_code": "instr", "title": "AMSR-2", "abstract": "Advanced Microwave Scanning Radiometer -2, flying on the Global Change Observation Mission (GCOM) series of satellites flown by JAXA" }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } }, { "ob_id": 12527, "platform": { "ob_id": 27130, "uuid": "526c6fb02e094d049d367aaa4f79e8d1", "short_code": "plat", "title": "Coriolis", "abstract": "The Coriolis satellite is flown by NASA and the US Department of Defence, with a primary mission to provide observations of the sea-surface wind. It carries two instruments: WindSat and SMEI (Solar Mass Ejection Imager)" }, "instrument": { "ob_id": 27125, "uuid": "10f4aca379f84e0cae56392a85604469", "short_code": "instr", "title": "WindSat", "abstract": "WindSat is a passive microwave radiometer flown on the Coriolis Satellite by the US Department of Defence since 2003." }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } }, { "ob_id": 12528, "platform": { "ob_id": 27128, "uuid": "9c6e8c73f539446ba7a8adef871492a7", "short_code": "plat", "title": "SMOS", "abstract": "The SMOS (Soil Moisture and Ocean Salinity) satellite was launched on Novermber 2009, with the primary mission to monitor ocean salinity and soil moisture." }, "instrument": { "ob_id": 27124, "uuid": "9b4be0d67030450ca8aebf37cf39500c", "short_code": "instr", "title": "MIRAS", "abstract": "MIRAS (Microwave Imaging Radiometer using Aperture Synthesis) is an European Space Agency instrument flown on the SMOS (Soil Moisture and Ocean Salinity) Satellite. It measures Ocean Salinity and Soil Moisture." }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } }, { "ob_id": 12530, "platform": { "ob_id": 32306, "uuid": "0cc9d1b2d73b4fe3983cbb95827b2581", "short_code": "plat", "title": "GPM - Core Observatory", "abstract": "The Global Precipitation Mission (GPM) - Core Observatory is an operational satellite flown by NASA and JAXA, and forms the main element of the Global Precipitation Measurement mission. It carries two instruments: DPR (Dual-frequency Precipitation Radar), and GMI (GPM Microwave Imager)" }, "instrument": { "ob_id": 32305, "uuid": "7db99f9f3e5d4e63bf748dc395124886", "short_code": "instr", "title": "GMI (core)", "abstract": "The GPM Microwave Imager (GPI) is a multipurpose imager flown on the Global Precipitation Mission (GPM) Core Observatory by NASA" }, "relatedTo": { "ob_id": 32308, "uuid": "ca2e0dad967e49fbaf4c5ec4cf314583", "short_code": "acq", "title": "Acquistion process for the ESA Soil Moisture Climate Change Initiative Combined product, v6.1", "abstract": "The ESA Climate Change Initiative Combined product has been derived from data from both active (AMI-SCAT, ASCAT) and passive satellite instruments (SMMR, SSM/I, TMI, AMSR-E, WindSat, AMSR2, MIRAS (SMOS), SMAP, FY-3B, GPM)" } } ] }, { "ob_id": 32318, "uuid": "93c0d4a2521a44758fa9bbb9c5706544", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2019_171a - HyTES19 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 32319, "uuid": "ef9e022c55f84b8ba4c4bc899d8c471f", "short_code": "mpop", "title": "ARSF flight 2019_171a", "abstract": "Flight details for NERC-ARSF aircraft flight number 2019_171a. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12531, "platform": { "ob_id": 6394, "uuid": "d2c5c36981824b71a98a2906394d61f3", "short_code": "plat", "title": "NERC ARSF Dornier Do228-101 D-CALM Aircraft", "abstract": "NERC leased Dornier 228 twin prop converted airliner\r\n\r\nDornier 228 D-CALM is a medium tropospheric research aircraft operated by NERC, UK. It has a twin turbo-prop powered non-pressurised shoulder-wing monoplane with rectangular-section fuselage and a double passenger/cargo door. The aircraft is used in the fields of optical remote sensing, oceanography, atmospheric and earth science research. A range of sensors may be installed.\r\n\r\nDimensions:\r\n\r\n Length: 15.04 m; Height: 4.86 m; Wingspan: 16.87 m; \r\n\r\n\r\nFlying performances:\r\n\r\n Speed:\r\n Min speed: 62 m/s\r\n Max speed: 83 m/s\r\n Usual speed during measurements: 65 m/s\r\n Usual speed during transit flights: 98 m/s\r\n Ascent rate: 1000 m/s\r\n\r\n Altitude:\r\n (1 ft = 0.31 m)\r\n Min altitude:\r\n Above sea: 200 ft\r\n Above ground: 500 ft\r\n Max ceiling: 22000 ft\r\n Usual ceiling during measurements: 15000 ft\r\n Ceiling limitations:\r\n The service ceiling for our normal operational science is 15 000ft. However, our maximum service ceiling is 22 000ft, dependent on crew oxygen and specific instrument hard-drive specifications. \r\n\r\n Payload:\r\n Empty weight: 3596 kg\r\n Max take-off weight: 5980 kg\r\n Max payload: 1595 kg\r\n Usual scientific payload during measurements: 500 kg\r\n Endurance:\r\n Max endurance: 7 h (at min scientific payload and max fuel) (Y-coordinate of 1st point)\r\n Endurance at max scientific payload: 5 h ... (Y-coordinate of 2nd point)\r\n \t\r\n Range:\r\n Max range: 2600 km (at min scientific payload and max fuel)\r\n Conditions for max range:\r\n FL150 at max fuel, speed = 180 KTAS\r\n Range at max scientific payload: 1800 km\r\n Usual range during measurement flight: 1500 km\r\n\r\n Other:\r\n Weather conditions limitations:\r\n VFR/IFR Approved Certified to fly in known icing conditions\r\n Take-off runway length: 625 m\r\n Engines:\r\n twin turbo-prop: Garrett TPE 331-5A-252 D with 533 kW (715 SHP) take-off power.;\r\n Avionics:\r\n INS, GPS, Transponder, DME, Weather radar, radio-altimeter \r\n\r\nCrew and scientists on board:\r\n\r\n Crew (pilots + operators): VFR: 1 pilotIFR: 2 pilots;\r\n Seats available for scientists: 1 operator seat, 3 potentially\r\n\r\nCabin:\r\n\r\n\r\n Apertures:\r\n Cargo door:\r\n Width : 1.28 m\r\n Height : 1.34 m;\r\n Cabin pressurized:\r\n none\r\n More information:\r\n Flexible accommodation for standard 19-inch racking, secured via the seat-rails.\r\n\r\n See below for additional information; \r\n\r\nAircraft modifications:\r\n\r\n Nose boom:\r\n none\r\n Windows:\r\n 2 Bubble-window with operator position and floor-opening for navigation-sight at the right forward side of the cabin\r\n Openings:\r\n Cabin floor, Back. One 2060 mm x 515 mm (frame 20 to 25) and one approx. 425mm diam (frame 25 to 27).\r\n Covered openings in the cabin roof - 400 mm diam back (between frame 23 and 24) - 150 mm diam fromt (frame 12/13) - 150 mm diam back(frame 22/23)\r\n Hard points:\r\n Six hardpoints below the cockpit-area for external loads up to 200 Kg- Each fuselage side (cockpit area) has three hardpoint\r\n -pairs to carry a load of 50 Kg (e.g. SLAR-antennae).\r\n -On both wings (outside of propwash) two wing-stations for external loads up to 100kg\r\n Inlets:\r\n One, installed on cabin roof aperture (frame 12/13), to accommodate Aerosol and/or whole-air inlets\r\n Additional systems:\r\n From the wing-stations to the cabin there are tubes for cables (power and data lines) pylons/pods to carry four Particle Measurement Systems (PMS) type probes. \r\n\r\nAcquisition systems:\r\n\r\n Leica ALS 50-II Lidar\r\n Leica RCD-105 39 Mega Pixel Digital Camera\r\n Specim Eagle & Hawk Hyperspectral Scanner\r\n Applanix POS and IPAS - Attitude and position\r\n\r\nElectrical power:\r\n\r\n Aircraft total electrical power (kW):\r\n 28V DC, 8.4 kW , 220 V AC, 2kW, 50 Hz \r\n Electrical power (kW) and voltages (V) available for scientists:\r\n DC 28 V – 6.3 kW of 28 volt DC total power, including a permanently installed 1.6kW / 220 V / 50 Hz inverter " }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 32318, "uuid": "93c0d4a2521a44758fa9bbb9c5706544", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2019_171a - HyTES19 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 32322, "uuid": "09f0a461f4bf44b09618bdf3e0e7bca0", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2019_171a - HyTES19 Flight: Airborne remote sensing measurements", "abstract": "Acquisition for: NERC-ARF 2019_171a - HyTES19 Flight: Airborne remote sensing measurements", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 32323, "uuid": "1ad030ab2b8f49a3b7c5eaa388759cf0", "short_code": "mpop", "title": "NERC-ARF flight 2019_171a", "abstract": "Flight details for NERC-ARF aircraft flight number 2019_171a. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12532, "platform": { "ob_id": 7575, "uuid": "2a863d6731c44af2aedda1da73e1015b", "short_code": "plat", "title": "BAS Twin-Otter aircraft", "abstract": "The British Antarctic Survey has a Twin Otter aircraft with a certified fit of airborne atmospheric instrumentation suitable for atmospheric, boundary layer and cloud/aerosol studies.\r\n\r\nThe Twin Otter aircraft is a very adaptable platform used the world over as a ‘bush’ aircraft. Its twin turbo-prop engines and ‘Short Take off and Landing’ (STOL) capability allow it to be used from small, remote unpaved airfields and the addition of skis or tundra tyres also allows operation on snow and from remote camps.\r\n\r\nThe aircraft can be operated single pilot and a long range fuel tank is also available. Double cargo doors provide good access for installing instrument racks.\r\n\r\nIn general the aircraft works in the Antarctic from October through to March each year depending on projects, and can operate at other latitudes outside this period, for example ACCACIA in the Arctic February 2013.\r\n\r\nThe instrument suite includes standard temperature and water vapour sensors as well as a turbulence probe allowing full atmospheric profile measurements of temperature, dew point and winds.\r\n\r\nThe fast turbulence probe also facilitates sensible heat flux measurements by the eddy covariance method. These boundary layer measurement capabilities are complemented by incoming and outgoing radiation instruments and a downward looking infra-red thermometer.\r\n\r\nThe floor hatch opening can also accommodate a fixed laser range finder or scanning laser which has been used for measuring ice floe topography. The required GPS and attitude measurements to support this are available. Video and digital SLR cameras can also be fitted here. The camera bay can also be configured to drop airborne deployable buoys.\r\n\r\nHard points and pylons are available on each wing. A DMT Cloud and aerosol spectrometer (CAPS) probe is used for cloud studies. Other standard PMS pod instruments can easily be accommodated. A closed path Licor H2O/CO2 instrument, Grimm optical particle counter and cloud condensation nuclei counter are fed from simple Rosemount inlets.\r\n\r\nRange:\t1000km including skis. Increased with long range tank depending on configuration.\r\nAirspeed:\tCruise 65m/s. Data collection 60m/s.\r\nComplement:\tPilot + maximum 4 mission operators / scientists.\r\nAltitudes:\tless than 35m to 5000m. Unpressurized but with oxygen fit for pilots and operators." }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 32322, "uuid": "09f0a461f4bf44b09618bdf3e0e7bca0", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2019_171a - HyTES19 Flight: Airborne remote sensing measurements", "abstract": "Acquisition for: NERC-ARF 2019_171a - HyTES19 Flight: Airborne remote sensing measurements" } } ] }, { "ob_id": 32442, "uuid": "ea79bc10eb944002abd4727383701aca", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2018_135a - GB18_56 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 32443, "uuid": "f26918281177475dbe7a846d117ce079", "short_code": "mpop", "title": "NERC-ARF flight 2018_135a", "abstract": "Flight details for NERC-ARF aircraft flight number 2018_135a. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12535, "platform": { "ob_id": 7575, "uuid": "2a863d6731c44af2aedda1da73e1015b", "short_code": "plat", "title": "BAS Twin-Otter aircraft", "abstract": "The British Antarctic Survey has a Twin Otter aircraft with a certified fit of airborne atmospheric instrumentation suitable for atmospheric, boundary layer and cloud/aerosol studies.\r\n\r\nThe Twin Otter aircraft is a very adaptable platform used the world over as a ‘bush’ aircraft. Its twin turbo-prop engines and ‘Short Take off and Landing’ (STOL) capability allow it to be used from small, remote unpaved airfields and the addition of skis or tundra tyres also allows operation on snow and from remote camps.\r\n\r\nThe aircraft can be operated single pilot and a long range fuel tank is also available. Double cargo doors provide good access for installing instrument racks.\r\n\r\nIn general the aircraft works in the Antarctic from October through to March each year depending on projects, and can operate at other latitudes outside this period, for example ACCACIA in the Arctic February 2013.\r\n\r\nThe instrument suite includes standard temperature and water vapour sensors as well as a turbulence probe allowing full atmospheric profile measurements of temperature, dew point and winds.\r\n\r\nThe fast turbulence probe also facilitates sensible heat flux measurements by the eddy covariance method. These boundary layer measurement capabilities are complemented by incoming and outgoing radiation instruments and a downward looking infra-red thermometer.\r\n\r\nThe floor hatch opening can also accommodate a fixed laser range finder or scanning laser which has been used for measuring ice floe topography. The required GPS and attitude measurements to support this are available. Video and digital SLR cameras can also be fitted here. The camera bay can also be configured to drop airborne deployable buoys.\r\n\r\nHard points and pylons are available on each wing. A DMT Cloud and aerosol spectrometer (CAPS) probe is used for cloud studies. Other standard PMS pod instruments can easily be accommodated. A closed path Licor H2O/CO2 instrument, Grimm optical particle counter and cloud condensation nuclei counter are fed from simple Rosemount inlets.\r\n\r\nRange:\t1000km including skis. Increased with long range tank depending on configuration.\r\nAirspeed:\tCruise 65m/s. Data collection 60m/s.\r\nComplement:\tPilot + maximum 4 mission operators / scientists.\r\nAltitudes:\tless than 35m to 5000m. Unpressurized but with oxygen fit for pilots and operators." }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 32442, "uuid": "ea79bc10eb944002abd4727383701aca", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2018_135a - GB18_56 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12536, "platform": { "ob_id": 7575, "uuid": "2a863d6731c44af2aedda1da73e1015b", "short_code": "plat", "title": "BAS Twin-Otter aircraft", "abstract": "The British Antarctic Survey has a Twin Otter aircraft with a certified fit of airborne atmospheric instrumentation suitable for atmospheric, boundary layer and cloud/aerosol studies.\r\n\r\nThe Twin Otter aircraft is a very adaptable platform used the world over as a ‘bush’ aircraft. Its twin turbo-prop engines and ‘Short Take off and Landing’ (STOL) capability allow it to be used from small, remote unpaved airfields and the addition of skis or tundra tyres also allows operation on snow and from remote camps.\r\n\r\nThe aircraft can be operated single pilot and a long range fuel tank is also available. Double cargo doors provide good access for installing instrument racks.\r\n\r\nIn general the aircraft works in the Antarctic from October through to March each year depending on projects, and can operate at other latitudes outside this period, for example ACCACIA in the Arctic February 2013.\r\n\r\nThe instrument suite includes standard temperature and water vapour sensors as well as a turbulence probe allowing full atmospheric profile measurements of temperature, dew point and winds.\r\n\r\nThe fast turbulence probe also facilitates sensible heat flux measurements by the eddy covariance method. These boundary layer measurement capabilities are complemented by incoming and outgoing radiation instruments and a downward looking infra-red thermometer.\r\n\r\nThe floor hatch opening can also accommodate a fixed laser range finder or scanning laser which has been used for measuring ice floe topography. The required GPS and attitude measurements to support this are available. Video and digital SLR cameras can also be fitted here. The camera bay can also be configured to drop airborne deployable buoys.\r\n\r\nHard points and pylons are available on each wing. A DMT Cloud and aerosol spectrometer (CAPS) probe is used for cloud studies. Other standard PMS pod instruments can easily be accommodated. A closed path Licor H2O/CO2 instrument, Grimm optical particle counter and cloud condensation nuclei counter are fed from simple Rosemount inlets.\r\n\r\nRange:\t1000km including skis. Increased with long range tank depending on configuration.\r\nAirspeed:\tCruise 65m/s. Data collection 60m/s.\r\nComplement:\tPilot + maximum 4 mission operators / scientists.\r\nAltitudes:\tless than 35m to 5000m. Unpressurized but with oxygen fit for pilots and operators." }, "instrument": { "ob_id": 24845, "uuid": "4f82e9e3c71140d499e7dbbe5d50da00", "short_code": "instr", "title": "NERC-ARF Specim AISA Owl", "abstract": "The Specim AISAOwl is a hyperspectral imager on board the NERC-ARF aircraft measuring the Long Wave InfraRed (LWIR) wavelengths, specifically 7.5–12.5 um with 102 bands. It is a passive pushbroom sensor measuring primarily emitted radiation, which can be used to derive temperature and emissivity." }, "relatedTo": { "ob_id": 32442, "uuid": "ea79bc10eb944002abd4727383701aca", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2018_135a - GB18_56 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 32446, "uuid": "a2dc229ee8e14bb7afb812e053b8b421", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2018_123 - CA18_207 Flight: Airborne remote sensing measurements", "abstract": "Acquisition for: NERC-ARF 2018_123 - CA18_207 Flight: Airborne remote sensing measurements", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 32435, "uuid": "67fd8c834def489da2aaf3d10b44ea9e", "short_code": "mpop", "title": "NERC-ARF flight 2018_123", "abstract": "Flight details for NERC-ARF aircraft flight number 2018_123. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12537, "platform": { "ob_id": 7575, "uuid": "2a863d6731c44af2aedda1da73e1015b", "short_code": "plat", "title": "BAS Twin-Otter aircraft", "abstract": "The British Antarctic Survey has a Twin Otter aircraft with a certified fit of airborne atmospheric instrumentation suitable for atmospheric, boundary layer and cloud/aerosol studies.\r\n\r\nThe Twin Otter aircraft is a very adaptable platform used the world over as a ‘bush’ aircraft. Its twin turbo-prop engines and ‘Short Take off and Landing’ (STOL) capability allow it to be used from small, remote unpaved airfields and the addition of skis or tundra tyres also allows operation on snow and from remote camps.\r\n\r\nThe aircraft can be operated single pilot and a long range fuel tank is also available. Double cargo doors provide good access for installing instrument racks.\r\n\r\nIn general the aircraft works in the Antarctic from October through to March each year depending on projects, and can operate at other latitudes outside this period, for example ACCACIA in the Arctic February 2013.\r\n\r\nThe instrument suite includes standard temperature and water vapour sensors as well as a turbulence probe allowing full atmospheric profile measurements of temperature, dew point and winds.\r\n\r\nThe fast turbulence probe also facilitates sensible heat flux measurements by the eddy covariance method. These boundary layer measurement capabilities are complemented by incoming and outgoing radiation instruments and a downward looking infra-red thermometer.\r\n\r\nThe floor hatch opening can also accommodate a fixed laser range finder or scanning laser which has been used for measuring ice floe topography. The required GPS and attitude measurements to support this are available. Video and digital SLR cameras can also be fitted here. The camera bay can also be configured to drop airborne deployable buoys.\r\n\r\nHard points and pylons are available on each wing. A DMT Cloud and aerosol spectrometer (CAPS) probe is used for cloud studies. Other standard PMS pod instruments can easily be accommodated. A closed path Licor H2O/CO2 instrument, Grimm optical particle counter and cloud condensation nuclei counter are fed from simple Rosemount inlets.\r\n\r\nRange:\t1000km including skis. Increased with long range tank depending on configuration.\r\nAirspeed:\tCruise 65m/s. Data collection 60m/s.\r\nComplement:\tPilot + maximum 4 mission operators / scientists.\r\nAltitudes:\tless than 35m to 5000m. Unpressurized but with oxygen fit for pilots and operators." }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 32446, "uuid": "a2dc229ee8e14bb7afb812e053b8b421", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2018_123 - CA18_207 Flight: Airborne remote sensing measurements", "abstract": "Acquisition for: NERC-ARF 2018_123 - CA18_207 Flight: Airborne remote sensing measurements" } }, { "ob_id": 12538, "platform": { "ob_id": 7575, "uuid": "2a863d6731c44af2aedda1da73e1015b", "short_code": "plat", "title": "BAS Twin-Otter aircraft", "abstract": "The British Antarctic Survey has a Twin Otter aircraft with a certified fit of airborne atmospheric instrumentation suitable for atmospheric, boundary layer and cloud/aerosol studies.\r\n\r\nThe Twin Otter aircraft is a very adaptable platform used the world over as a ‘bush’ aircraft. Its twin turbo-prop engines and ‘Short Take off and Landing’ (STOL) capability allow it to be used from small, remote unpaved airfields and the addition of skis or tundra tyres also allows operation on snow and from remote camps.\r\n\r\nThe aircraft can be operated single pilot and a long range fuel tank is also available. Double cargo doors provide good access for installing instrument racks.\r\n\r\nIn general the aircraft works in the Antarctic from October through to March each year depending on projects, and can operate at other latitudes outside this period, for example ACCACIA in the Arctic February 2013.\r\n\r\nThe instrument suite includes standard temperature and water vapour sensors as well as a turbulence probe allowing full atmospheric profile measurements of temperature, dew point and winds.\r\n\r\nThe fast turbulence probe also facilitates sensible heat flux measurements by the eddy covariance method. These boundary layer measurement capabilities are complemented by incoming and outgoing radiation instruments and a downward looking infra-red thermometer.\r\n\r\nThe floor hatch opening can also accommodate a fixed laser range finder or scanning laser which has been used for measuring ice floe topography. The required GPS and attitude measurements to support this are available. Video and digital SLR cameras can also be fitted here. The camera bay can also be configured to drop airborne deployable buoys.\r\n\r\nHard points and pylons are available on each wing. A DMT Cloud and aerosol spectrometer (CAPS) probe is used for cloud studies. Other standard PMS pod instruments can easily be accommodated. A closed path Licor H2O/CO2 instrument, Grimm optical particle counter and cloud condensation nuclei counter are fed from simple Rosemount inlets.\r\n\r\nRange:\t1000km including skis. Increased with long range tank depending on configuration.\r\nAirspeed:\tCruise 65m/s. Data collection 60m/s.\r\nComplement:\tPilot + maximum 4 mission operators / scientists.\r\nAltitudes:\tless than 35m to 5000m. Unpressurized but with oxygen fit for pilots and operators." }, "instrument": { "ob_id": 24847, "uuid": "4557fda0ad78453ca5658354289e1370", "short_code": "instr", "title": "NERC-ARF Leica RCD105", "abstract": "The Leica RCD105 medium format digital camera produces 16 bit TIFF digital images at 7216x5412 resolution (39 Mega-pixels)." }, "relatedTo": { "ob_id": 32446, "uuid": "a2dc229ee8e14bb7afb812e053b8b421", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2018_123 - CA18_207 Flight: Airborne remote sensing measurements", "abstract": "Acquisition for: NERC-ARF 2018_123 - CA18_207 Flight: Airborne remote sensing measurements" } } ] }, { "ob_id": 32450, "uuid": "e3a576bd97af4abf9f1d6d499afee38d", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2018_135b - GB18_56 Flight: Airborne remote sensing measurements", "abstract": "", "imageDetails": [], "mobilePlatformOperation": [ { "ob_id": 32451, "uuid": "795d66fa3fcf40f9a3c170496c5ec499", "short_code": "mpop", "title": "NERC-ARF flight 2018_135b", "abstract": "Flight details for NERC-ARF aircraft flight number 2018_135b. See linked documentation for further details." } ], "independentInstrument": [], "instrumentplatformpair_set": [ { "ob_id": 12539, "platform": { "ob_id": 7575, "uuid": "2a863d6731c44af2aedda1da73e1015b", "short_code": "plat", "title": "BAS Twin-Otter aircraft", "abstract": "The British Antarctic Survey has a Twin Otter aircraft with a certified fit of airborne atmospheric instrumentation suitable for atmospheric, boundary layer and cloud/aerosol studies.\r\n\r\nThe Twin Otter aircraft is a very adaptable platform used the world over as a ‘bush’ aircraft. Its twin turbo-prop engines and ‘Short Take off and Landing’ (STOL) capability allow it to be used from small, remote unpaved airfields and the addition of skis or tundra tyres also allows operation on snow and from remote camps.\r\n\r\nThe aircraft can be operated single pilot and a long range fuel tank is also available. Double cargo doors provide good access for installing instrument racks.\r\n\r\nIn general the aircraft works in the Antarctic from October through to March each year depending on projects, and can operate at other latitudes outside this period, for example ACCACIA in the Arctic February 2013.\r\n\r\nThe instrument suite includes standard temperature and water vapour sensors as well as a turbulence probe allowing full atmospheric profile measurements of temperature, dew point and winds.\r\n\r\nThe fast turbulence probe also facilitates sensible heat flux measurements by the eddy covariance method. These boundary layer measurement capabilities are complemented by incoming and outgoing radiation instruments and a downward looking infra-red thermometer.\r\n\r\nThe floor hatch opening can also accommodate a fixed laser range finder or scanning laser which has been used for measuring ice floe topography. The required GPS and attitude measurements to support this are available. Video and digital SLR cameras can also be fitted here. The camera bay can also be configured to drop airborne deployable buoys.\r\n\r\nHard points and pylons are available on each wing. A DMT Cloud and aerosol spectrometer (CAPS) probe is used for cloud studies. Other standard PMS pod instruments can easily be accommodated. A closed path Licor H2O/CO2 instrument, Grimm optical particle counter and cloud condensation nuclei counter are fed from simple Rosemount inlets.\r\n\r\nRange:\t1000km including skis. Increased with long range tank depending on configuration.\r\nAirspeed:\tCruise 65m/s. Data collection 60m/s.\r\nComplement:\tPilot + maximum 4 mission operators / scientists.\r\nAltitudes:\tless than 35m to 5000m. Unpressurized but with oxygen fit for pilots and operators." }, "instrument": { "ob_id": 20341, "uuid": "dc1c1ce7a82c4443b959edbf89c014d0", "short_code": "instr", "title": "NERC-ARF AsiaFENIX hyperspectral imager", "abstract": "The AisaFENIX dual sensor delivers high-quality hyperspectral data available in visible and SWIR wavelengths (380 - 2500nm) in a single continuous image. AisaFENIX eliminates past challenges in 'full spectrum imaging'. It is a single optics imager, with two focal plane arrays always staring exactly the same spot of the object. Thus, there is no need for the co-alignment of two separate imagers with different distortions, sharpness, and FOV.\r\n\r\nThe patent pending AisaFENIX images the target in 380 - 2500nm spectral region through single front optics and single input slit, keeping all wavebands spatially, co-registered, independent of the distance to the target. AisaFENIX employs Specim's patent pending 'single optics dual channel imaging spectrograph' which, in spite of the single input slit, has two diffraction gratings, one optimised for VNIR and the second for SWIR region. Also, two focal plane arrays (FPA), a state of the art CMOS and cryogenically cooled Mercury Telluride Cadmium (MCT), are employed in order to maximise sensitivity and signal-to-noise ratio (SNR) in the VNIR and SWIR spectral region.\r\n\r\nThe AsiaFENIX is operated by NERC-ARF on board the British Antarctic Survey (BAS) Twin-Otter aircraft (Pre 2016 it was operated on board the NERC ARSF Dornier Do228-101 D-CALM Aircraft)" }, "relatedTo": { "ob_id": 32450, "uuid": "e3a576bd97af4abf9f1d6d499afee38d", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2018_135b - GB18_56 Flight: Airborne remote sensing measurements", "abstract": "" } }, { "ob_id": 12540, "platform": { "ob_id": 7575, "uuid": "2a863d6731c44af2aedda1da73e1015b", "short_code": "plat", "title": "BAS Twin-Otter aircraft", "abstract": "The British Antarctic Survey has a Twin Otter aircraft with a certified fit of airborne atmospheric instrumentation suitable for atmospheric, boundary layer and cloud/aerosol studies.\r\n\r\nThe Twin Otter aircraft is a very adaptable platform used the world over as a ‘bush’ aircraft. Its twin turbo-prop engines and ‘Short Take off and Landing’ (STOL) capability allow it to be used from small, remote unpaved airfields and the addition of skis or tundra tyres also allows operation on snow and from remote camps.\r\n\r\nThe aircraft can be operated single pilot and a long range fuel tank is also available. Double cargo doors provide good access for installing instrument racks.\r\n\r\nIn general the aircraft works in the Antarctic from October through to March each year depending on projects, and can operate at other latitudes outside this period, for example ACCACIA in the Arctic February 2013.\r\n\r\nThe instrument suite includes standard temperature and water vapour sensors as well as a turbulence probe allowing full atmospheric profile measurements of temperature, dew point and winds.\r\n\r\nThe fast turbulence probe also facilitates sensible heat flux measurements by the eddy covariance method. These boundary layer measurement capabilities are complemented by incoming and outgoing radiation instruments and a downward looking infra-red thermometer.\r\n\r\nThe floor hatch opening can also accommodate a fixed laser range finder or scanning laser which has been used for measuring ice floe topography. The required GPS and attitude measurements to support this are available. Video and digital SLR cameras can also be fitted here. The camera bay can also be configured to drop airborne deployable buoys.\r\n\r\nHard points and pylons are available on each wing. A DMT Cloud and aerosol spectrometer (CAPS) probe is used for cloud studies. Other standard PMS pod instruments can easily be accommodated. A closed path Licor H2O/CO2 instrument, Grimm optical particle counter and cloud condensation nuclei counter are fed from simple Rosemount inlets.\r\n\r\nRange:\t1000km including skis. Increased with long range tank depending on configuration.\r\nAirspeed:\tCruise 65m/s. Data collection 60m/s.\r\nComplement:\tPilot + maximum 4 mission operators / scientists.\r\nAltitudes:\tless than 35m to 5000m. Unpressurized but with oxygen fit for pilots and operators." }, "instrument": { "ob_id": 24845, "uuid": "4f82e9e3c71140d499e7dbbe5d50da00", "short_code": "instr", "title": "NERC-ARF Specim AISA Owl", "abstract": "The Specim AISAOwl is a hyperspectral imager on board the NERC-ARF aircraft measuring the Long Wave InfraRed (LWIR) wavelengths, specifically 7.5–12.5 um with 102 bands. It is a passive pushbroom sensor measuring primarily emitted radiation, which can be used to derive temperature and emissivity." }, "relatedTo": { "ob_id": 32450, "uuid": "e3a576bd97af4abf9f1d6d499afee38d", "short_code": "acq", "title": "Acquisition for: NERC-ARF 2018_135b - GB18_56 Flight: Airborne remote sensing measurements", "abstract": "" } } ] }, { "ob_id": 32463, "uuid": "0139762429424deab7851a48a4f34931", "short_code": "acq", "title": "Indoor air population study: Volatile Organic Compounds (VOC) concentrations", "abstract": "Indoor air population study: Volatile Organic Compounds (VOC) concentrations", "imageDetails": [], "mobilePlatformOperation": [], "independentInstrument": [ 3181, 19007 ], "instrumentplatformpair_set": [] } ] }