Procedure Composite Process Instance
Get a list of ProcedureComputation objects. ProcedureComputations have a 1:1 mapping with Observations where used.
These may have a number of 2 or more components made up of combinations of Computation and Acquisition records.
The details of the underlying records have been serialised.
### Available end points:
- `/ProcedureComputations/` - Will list all ProcedureComputations in the database
- `/ProcedureComputations.json` - Will return all ProcedureComputations in json format
- `/ProcedureComputations/<object_id>/` - Returns ProcedureComputations object with that id
### Available Methods:
- `GET`
- `HEAD`
### Available filters:
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### How to use filters:
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GET /api/v2/composites/3916/?format=api
{ "ob_id": 3916, "computationComponent": [ { "ob_id": 3914, "uuid": "c4be2417e6ed4b4c982fb1c82bd1ce76", "title": "CAM 3.5 - Interim version of the NCAR Community Atmospheric Model deployed on National Centre for Atmospheric Research (USA) computing facility", "abstract": "This computation involved: CAM 3.5 - Interim version of the NCAR Community Atmospheric Model deployed on National Centre for Atmospheric Research (USA) computing facility. The CAM3.5 (NCAR Community Atmosphere Model, version 3.5) is a atmospheric model developed by the NCAR in collaboration with the climate modelling community.\r\n\r\nThis version is the recently improved version of the state-of-the-art atmospheric general circulation model (AGCM) and serves as an interim version in the process of improving the model physics for the next-generation CAM, version 4 (CAM4), which is a global primitive-equation model with 26 vertical levels.\r\n\r\nThe version 3.5 of the CAM model is closely related to the previous CAM 3.0 version. Main modifications include changes to:\r\n - convective and cloud processes; the calculation of cloud fraction is updated \r\n - the land model: new hydrology, surface datasets an canopy integration were introduced.\r\n - chemistry modules\r\n\r\nThe above changes are documented in Oleson et al. 2008; Stockli et al. 2008; Neale et al. 2008; Richter and Rasch 2008; Gent et al. 2009; Chen et al. 2010.\r\n\r\n\r\nThe horizontal and vertical representation, resolution and parameterization characteristics are in CAM3.0 as follows (2009):\r\n \r\nA. Atmosphere\r\n - resolution\r\n\t- Horizontal : \r\n\t\tFor spectral dynamics the horizonal grid is Gaussian and is specified as nlat x nlon where nlat is the number of Gaussian latitudes and nlon is the number of distinct longitudes. For finite-volume dynamics the meridional grid is equally spaced and includes the pole points. It is specified as dlatxdlon where dlat is the latitude cell size and dlon is the longitude cell size, both in degrees. All of the valid resolutions are listed in the resolution_parameters.xml file in the configuration script directory. Commonly used resolutions include 48x96, 64x128, and 128x256 for the spectral dynamic cores, and 2x2.5 for the Finite-Volume dynamic core.\r\n\t- Vertical :\r\n\t\tHybrid sigma-pressure. 26 levels. \r\n\t\t\r\n\t\tMore details on the theoretical nature of the vertical coordinate system can be found in Collins et al. (2004). \r\n\r\n - parametrizations\r\n\tThe CAM 3.0 cleanly separates the parameterization suite from the dynamical core, and makes it easier to replace or modify each in isolation. The dynamical core can be coupled to the parameterization suite in a purely time split manner or in a purely process split one. The Process Split form is convenient for spectral transform models. With Time Split approximations extra spectral transforms are required to convert the updated momentum variables provided by the parameterizations to vorticity and divergence for the Eulerian spectral core, or to recalculate the temperature gradient for the semi-Lagrangian spectral core. The Time Split form is convenient for the finite-volume core which adopts a Lagrangian vertical coordinate. Since the scheme is explicit and restricted to small time-steps by its non-advective component, it sub-steps the dynamics multiple times during a longer parameterization time step. With Process Split approximations the forcing terms must be interpolated to an evolving Lagrangian vertical coordinate every sub-step of the dynamical core. Besides the expense involved, it is not completely obvious how to interpolate the parameterized forcing, which can have a vertical grid scale component arising from vertical grid scale clouds, to a different vertical grid. More about Process Split and Time Split approximations is explained in Williamson (2002)\r\n \r\n\tThe total parameterization package in CAM 3.0 consists of a sequence of components, indicated by\r\n\r\n\t$\\displaystyle P = { M,R,S,T }\r\n\r\n\twhere \r\n\t\tM denotes (Moist) precipitation processes, \r\n\t\tR denotes clouds and Radiation, \r\n\t\tS denotes the Surface model, and \r\n\t\tT denotes Turbulent mixing. \r\n\t\r\n\tEach of these in turn is subdivided into various components: \r\n\t\tM includes an optional dry adiabatic adjustment (normally applied only in the stratosphere), moist penetrative convection, shallow convection, and large-scale stable condensation; \r\n\t\tR first calculates the cloud parameterization followed by the radiation parameterization;\r\n\t\tS provides the surface fluxes obtained from land, ocean and sea ice models, or calculates them based on specified surface conditions such as sea surface temperatures and sea ice distribution. These surface fluxes provide lower flux boundary conditions for the turbulent mixing\r\n\t\tT which is comprised of the planetary boundary layer parameterization, vertical diffusion, and gravity wave drag.\r\n\r\n\tSee linked documentation for further details on the parameterisation schemes.\r\n\r\n\t\r\nMore on NCAR Community Atmosphere Model (CAM3) can be found in the online documentation links attached to this record. \r\n\r\n NCAR’s (National Centre for Atmospheric Research) supercomputing resources serve nearly 1,300 users in a wide variety of disciplines including climatology, meteorology, oceanography, astrophysics, fluid dynamics, and turbulence. In particular, CISL (Computational Information Systems Laboratory) provisions a balanced suite of high-performance resources that allows today’s Earth System models to simulate atmosphere, ocean, sea ice, and land surface processes with increasing fidelity.\r\n", "keywords": "", "inputDescription": null, "outputDescription": null, "softwareReference": null, "identifier_set": [ "https://api.catalogue.ceda.ac.uk/api/v2/identifiers/2662/?format=api", "https://api.catalogue.ceda.ac.uk/api/v2/identifiers/2663/?format=api", "https://api.catalogue.ceda.ac.uk/api/v2/identifiers/2664/?format=api" ] }, { "ob_id": 3915, "uuid": "0fd61e5a4dec4111ba19fa1e5c7c5bc4", "title": "CAM 5.1 - Interim version of the NCAR Community Atmospheric Model deployed on unknown computer", "abstract": "This computation involved: CAM 5.1 - Interim version of the NCAR Community Atmospheric Model. Version 5.1 of the Community Atmosphere Model (CAM) is the latest in a series of global atmosphere models originally developed at the National Center for Atmospheric Research (NCAR). CAM is used as both a standalone model and as the atmospheric component of the Community Earth System Model (CESM).\n\n<div property=\"cedacat:introduction\">\n<div class=\"introduction\">Introduction</div>\nVersion 5.1 of the Community Atmosphere Model (CAM) is the latest in a series of global atmosphere models originally developed at the National Center for Atmospheric Research (NCAR). CAM is used as both a standalone model and as the atmospheric component of the Community Earth System Model (CESM).\n</div>", "keywords": "", "inputDescription": null, "outputDescription": null, "softwareReference": null, "identifier_set": [ "https://api.catalogue.ceda.ac.uk/api/v2/identifiers/2665/?format=api", "https://api.catalogue.ceda.ac.uk/api/v2/identifiers/2666/?format=api" ] } ], "acquisitionComponent": [], "identifier_set": [], "responsiblepartyinfo_set": [] }