Property:Describe output parameters model
From CSDMS
This is a property of type Text.
S
"sediment_fill__depth":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Depth of sediment added at eachnode",
}
"topographic__elevation":
{
"dtype": float,
"intent": "inout",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
} +
E
"soil__depth":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Depth of soil or weathered bedrock",
}
"soil_production__rate":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m/yr",
"mapping": "node",
"doc": "rate of soil production at nodes",
} +
T
"soil__flux":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m^2/yr",
"mapping": "link",
"doc": "flux of soil in direction of link",
}
"topographic__elevation":
{
"dtype": float,
"intent": "inout",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
}
"topographic__slope":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m/m",
"mapping": "link",
"doc": "gradient of the ground surface",
} +
V
"surface__evapotranspiration":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "mm",
"mapping": "cell",
"doc": "actual sum of evaporation and plant transpiration",
}
"surface__potential_evapotranspiration_30day_mean":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "mm",
"mapping": "cell",
"doc": "30 day mean of surface__potential_evapotranspiration",
}
"surface__potential_evapotranspiration_rate":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "mm",
"mapping": "cell",
"doc": "potential sum of evaporation and potential transpiration",
}
"vegetation__cover_fraction":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "None",
"mapping": "cell",
"doc": "fraction of land covered by vegetation",
}
"vegetation__dead_biomass":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "g m^-2 d^-1",
"mapping": "cell",
"doc": "weight of dead organic mass per unit area - measured in terms of dry matter",
}
"vegetation__dead_leaf_area_index":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "None",
"mapping": "cell",
"doc": "one-sided dead leaf area per unit ground surface area",
}
"vegetation__live_biomass":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "g m^-2 d^-1",
"mapping": "cell",
"doc": "weight of green organic mass per unit area - measured in terms of dry matter",
}
"vegetation__live_leaf_area_index":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "None",
"mapping": "cell",
"doc": "one-sided green leaf area per unit ground surface area",
}
"vegetation__plant_functional_type":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "None",
"mapping": "cell",
"doc": "classification of plants (int), grass=0, shrub=1, tree=2, bare=3, shrub_seedling=4, tree_seedling=5",
}
"vegetation__water_stress":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "None",
"mapping": "cell",
"doc": "parameter that represents nonlinear effects of water deficit on plants",
}
O
"surface_water__depth":
{
"dtype": float,
"intent": "inout",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Depth of water on the surface",
} +
S
"taxa__richness":
{
"dtype": int,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "The number of taxa at each node",
} +
P
"topographic__elevation":
{
"dtype": float,
"intent": "inout",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
} +
N
"topographic__elevation":
{
"dtype": float,
"intent": "inout",
"optional": True,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
} +
D
* Query particle locations and travel times at a given iteration
* Query particle locations at a given travel time
* Plot the particle exposure time distributions
* Animate the output images of particle locations
* Plot the travel paths specified particles have taken
* Plot the particle positions for a specified iteration or travel time
+
A
B
C
F
-- +
I
M
-- +
S
-- +
E
F
S
W
B
C
S
C
T
F
C
F
I
A
-- +
-- +
B
D
-- +
F
-- +
G
-- +
R
-- +
S
-- +
-- +
W
-- +
Q
R
D
-- +
L
U
-- +
A
L
-- +
F
1-D Metrics: (channel width, bank height, floodplain width); 2-D Metrics: (floodplain 2D metrics); 2-D HAND Metrics: (channel width and floodplain width) +
R
2-dimensional distributions of the following:
* Vegetation community (high- or low-flow-resistance)
* Depth-averaged flow speed and directional components
* Bed shear stress
* Soil elevation
* Suspended sediment concentration +
D
P
3D fields of temperature, salinity, velocity, turbulent kinetic energy; 2D fields of surface elevation, vertically averaged velocity, stream function. +
D
3D grid of the simulated basin (cartesian grid), + properties (depositional bathymetry, lithology, facies, porosity, ...) +
S
3D stratigraphy (age, provenance, grainsize, peat fraction)<br>Morphodynamic maps of grainsize, discharge, sediment erosion and deposition +
C
A 3D cube of model strata coded by water depth of deposition and thickness transported versus thickness deposited in-situ per time step +
N
A plot, and/or the value of the NetCDF file at the designated cell +
E
A sequence of grids that represent DEMs at different times in the evolution. Saved in RTS (RiverTools Sequence) format with RTI file for georeferencing. +
I
A web page displaying skill scores for the models and plots (PNG) of the spatial distribution of model outputs versus benchmark data. +
S
After infiltration occurs, the component returns an updated 'surface_water__depth' field, as well as an updated 'soil_water_infiltration__depth' field that tracks how much water has been infiltrated into the soil column. +
F
Air Frost number +
L
Although the model’s primary output product is channel discharge, all internal rate and state variables (soil moisture, for example) can also be written as output. In addition, all output can be written as grids, or time series at user-defined points or areas. The user has complete control over how output is written, thus minimising any waste of disk space or CPU time. +
S
W
B
Barrier elevation grid, cross-shore location of ocean and back-barrier shorelines, dune elevations, overwash flux, shoreface flux, shrub cover +
G
Barrier island morphology and stratigraphy and migration rate.
See User's Guide and Moore et al., 2010 for more details. +
Barrier island, marsh, and bay morphology and stratigraphy over time.
See User's Guide and Moore et al., 2010 for more details. +
C
Benthic carbonate accumulation; sediment character and thickness; organism stocks and remains; environmental history; 2D-3D map graphics; graphs of stocks and vacant seafloor through time. +
O
Bottom wave orbital velocity. Also surface wave conditions if calculated from wind speed. +
C
CREST outputs consist of several variables, including:
*storage depths of the vegetation canopy,
*the three soil layers, and two linear reservoirs,
*relative change of the six reservoir levels representing actual evapotranspiration from the canopy and soil layers,
*overland and interflow excess rain,
* overland and interflow runoff. +
S
I
