Property:Describe output parameters model
From CSDMS
This is a property of type Text.
S
"channel__bed_shear_stress":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "Pa",
"mapping": "node",
"doc": "Shear exerted on the bed of the channel, assuming all discharge travels along a single, self-formed channel",
}
"channel__depth":
{
"dtype": float,
"intent": "out",
"optional": True,
"units": "m",
"mapping": "node",
"doc": "Depth of the a single channel carrying all runoff through the node",
}
"channel__discharge":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m**3/s",
"mapping": "node",
"doc": "Volumetric water flux of the a single channel carrying all runoff through the node",
}
"channel__width":
{
"dtype": float,
"intent": "out",
"optional": True,
"units": "m",
"mapping": "node",
"doc": "Width of the a single channel carrying all runoff through the node",
}
"channel_sediment__relative_flux":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "The fluvial_sediment_flux_into_node divided by the fluvial_sediment_transport_capacity",
}
"channel_sediment__volumetric_flux":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m**3/s",
"mapping": "node",
"doc": "Total volumetric fluvial sediment flux brought into the node from upstream",
}
"channel_sediment__volumetric_transport_capacity":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m**3/s",
"mapping": "node",
"doc": "Volumetric transport capacity of a channel carrying all runoff through the node, assuming the Meyer-Peter Muller transport equation",
}
"drainage_area":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m**2",
"mapping": "node",
"doc": "Upstream accumulated surface area contributing to the node's discharge",
}
"flow__link_to_receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "ID of link downstream of each node, which carries the discharge",
}
"flow__receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array of receivers (node that receives flow from current node)",
}
"flow__upstream_node_order":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array containing downstream-to-upstream ordered list of node IDs",
}
"topographic__elevation":
{
"dtype": float,
"intent": "inout",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
}
"topographic__steepest_slope":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "The steepest *downhill* slope",
}
C
"channel__chi_index":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "variable",
"mapping": "node",
"doc": "the local steepness index",
},
"drainage_area":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m**2",
"mapping": "node",
"doc": "Upstream accumulated surface area contributing to the node's discharge",
},
"flow__link_to_receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "ID of link downstream of each node, which carries the discharge",
},
"flow__receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array of receivers (node that receives flow from current node)",
},
"flow__upstream_node_order":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array containing downstream-to-upstream ordered list of node IDs",
},
"topographic__elevation":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
},
"topographic__steepest_slope":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "The steepest *downhill* slope",
} +
S
"channel__steepness_index":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "variable",
"mapping": "node",
"doc": "the local steepness index",
}
"drainage_area":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m**2",
"mapping": "node",
"doc": "Upstream accumulated surface area contributing to the node's discharge",
}
"flow__link_to_receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "ID of link downstream of each node, which carries the discharge",
}
"flow__receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array of receivers (node that receives flow from current node)",
}
"flow__upstream_node_order":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array containing downstream-to-upstream ordered list of node IDs",
}
"topographic__elevation":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
}
"topographic__steepest_slope":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "The steepest *downhill* slope",
} +
D
"depression__depth":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Depth of depression below its spillway point",
}
"depression__outlet_node":
{
"dtype": int,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "If a depression, the id of the outlet node for that depression, otherwise grid.BAD_INDEX",
}
"flood_status_code":
{
"dtype": int,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Map of flood status (_PIT, _CURRENT_LAKE, _UNFLOODED, or _FLOODED).",
}
"is_pit":
{
"dtype": bool,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Boolean flag indicating whether a node is a pit.",
}
"topographic__elevation":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
} +
H
"distance_to_divide":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Distance from drainage divide.",
}
"drainage_area":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m**2",
"mapping": "node",
"doc": "Upstream accumulated surface area contributing to the node's discharge",
}
"flow__link_to_receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "ID of link downstream of each node, which carries the discharge",
}
"flow__receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array of receivers (node that receives flow from current node)",
}
"flow__upstream_node_order":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array containing downstream-to-upstream ordered list of node IDs",
}
"topographic__elevation":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
} +
C
"drainage_area":
{
"dtype": float,
"intent": "in",
"optional": True,
"units": "m**2",
"mapping": "node",
"doc": "Upstream accumulated surface area contributing to the node's discharge",
},
"flow__link_to_receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "ID of link downstream of each node, which carries the discharge",
},
"flow__receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array of receivers (node that receives flow from current node)",
} +
F
"drainage_area":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m**2",
"mapping": "node",
"doc": "Upstream accumulated surface area contributing to the node's discharge",
}
"flow__link_to_receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "ID of link downstream of each node, which carries the discharge",
}
"flow__receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array of receivers (node that receives flow from current node)",
}
"flow__upstream_node_order":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array containing downstream-to-upstream ordered list of node IDs",
}
"topographic__elevation":
{
"dtype": float,
"intent": "inout",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
} +
S
"drainage_area":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m**2",
"mapping": "node",
"doc": "Upstream accumulated surface area contributing to the node's discharge",
}
"flow__link_to_receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "ID of link downstream of each node, which carries the discharge",
}
"flow__receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array of receivers (node that receives flow from current node)",
}
"flow__upstream_node_order":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array containing downstream-to-upstream ordered list of node IDs",
}
"topographic__elevation":
{
"dtype": float,
"intent": "inout",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
} +
L
"drainage_area":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m**2",
"mapping": "node",
"doc": "Upstream accumulated surface area contributing to the node's discharge",
}
"flow__receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array of receivers (node that receives flow from current node)",
}
"flow__upstream_node_order":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array containing downstream-to-upstream ordered list of node IDs",
}
"lateral_erosion__depth_increment":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Change in elevation at each node from lateral erosion during time step",
}
"sediment__flux":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m3/y",
"mapping": "node",
"doc": "Sediment flux (volume per unit time of sediment entering each node)",
}
"topographic__elevation":
{
"dtype": float,
"intent": "inout",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
}
"topographic__steepest_slope":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "The steepest *downhill* slope",
}
"volume__lateral_erosion":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m3",
"mapping": "node",
"doc": "Array tracking volume eroded at each node from lateral erosion",
} +
F
"flow__link_direction":
{
"dtype": np.int8,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "link",
"doc": "Direction of flow on link. A value of -1 indicates that water flow goes from head node to tail node, while a value of 1 indicates that water flow goes from tail node to head node.",
}
"flow__link_to_receiver_node":
{
"dtype": int,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "ID of link downstream of each node, which carries the discharge",
}
"flow__receiver_node":
{
"dtype": int,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array of receivers (node that receives flow from current node)",
}
"flow__sink_flag":
{
"dtype": bool,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Boolean array, True at local lows",
}
"topographic__elevation":
{
"dtype": float,
"intent": "in",
"optional": True,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
}
"topographic__steepest_slope":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "The steepest *downhill* slope",
} +
"flow__link_to_receiver_node":
{
"dtype": int,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "ID of link downstream of each node, which carries the discharge",
}
"flow__receiver_node":
{
"dtype": int,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array of receivers (node that receives flow from current node)",
}
"flow__sink_flag":
{
"dtype": bool,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Boolean array, True at local lows",
}
"topographic__elevation":
{
"dtype": float,
"intent": "in",
"optional": True,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
}
"topographic__steepest_slope":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "The steepest *downhill* slope",
} +
P
"flow__potential":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m**3/s",
"mapping": "node",
"doc": "Value of the hypothetical field 'K', used to force water flux to flow downhill",
}
"surface_water__depth":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Depth of water on the surface",
}
"surface_water__discharge":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m**3/s",
"mapping": "node",
"doc": "Volumetric discharge of surface water",
}
"topographic__elevation":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
}
"water__unit_flux_in":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m/s",
"mapping": "node",
"doc": "External volume water per area per time input to each node (e.g., rainfall rate)",
} +
T
"flow__receiver_node":
{
"dtype": int,
"intent": "in",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Node array of receivers (node that receives flow from current node)",
}
"sediment__deposition_coeff":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "Fraction of incoming sediment that is deposited on the node",
}
"sediment__deposition_rate":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m/yr",
"mapping": "node",
"doc": "Deposition rate on node",
}
"sediment__erosion_rate":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m/yr",
"mapping": "node",
"doc": "Erosion rate on node",
}
"sediment__flux_in":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m/yr",
"mapping": "node",
"doc": "Incoming sediment rate on node (=qs/dx)",
}
"sediment__flux_out":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m/yr",
"mapping": "node",
"doc": "Outgoing sediment rate on node = sediment eroded on node + sediment transported across node from upstream",
}
"sediment__transfer_rate":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m/yr",
"mapping": "node",
"doc": "Rate of transferred sediment across a node (incoming sediment - deposited sediment on node)",
}
"topographic__elevation":
{
"dtype": float,
"intent": "inout",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
}
"topographic__steepest_slope":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m/m",
"mapping": "node",
"doc": "The steepest *downhill* slope",
} +
F
"fracture_at_node":
{
"dtype": np.int8,
"intent": "out",
"optional": False,
"units": "-",
"mapping": "node",
"doc": "presence (1) or absence (0) of fracture",
} +
L
"landslide__probability_of_failure":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "None",
"mapping": "node",
"doc": "number of times FS is <=1 out of number of iterations user selected",
}
"soil__density":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "kg/m3",
"mapping": "node",
"doc": "wet bulk density of soil",
}
"soil__internal_friction_angle":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "degrees",
"mapping": "node",
"doc": "critical angle just before failure due to friction between particles",
}
"soil__maximum_total_cohesion":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "Pa or kg/m-s2",
"mapping": "node",
"doc": "maximum of combined root and soil cohesion at node",
}
"soil__mean_relative_wetness":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "None",
"mapping": "node",
"doc": "Indicator of soil wetness; relative depth perched water table within the soil layer",
}
"soil__minimum_total_cohesion":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "Pa or kg/m-s2",
"mapping": "node",
"doc": "minimum of combined root and soil cohesion at node",
}
"soil__mode_total_cohesion":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "Pa or kg/m-s2",
"mapping": "node",
"doc": "mode of combined root and soil cohesion at node",
}
"soil__probability_of_saturation":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "None",
"mapping": "node",
"doc": "number of times relative wetness is >=1 out of number of iterations user selected",
}
"soil__saturated_hydraulic_conductivity":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m/day",
"mapping": "node",
"doc": "mode rate of water transmitted through soil - provided if transmissivity is NOT provided to calculate tranmissivity with soil depth",
}
"soil__thickness":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "soil depth to restrictive layer",
}
"soil__transmissivity":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m2/day",
"mapping": "node",
"doc": "mode rate of water transmitted through a unit width of saturated soil - either provided or calculated with Ksat and soil depth",
}
"topographic__slope":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "tan theta",
"mapping": "node",
"doc": "gradient of the ground surface",
}
"topographic__specific_contributing_area":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "specific contributing (upslope area/cell face ) that drains to node",
}
F
"lithosphere__overlying_pressure_increment":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "Pa",
"mapping": "node",
"doc": "Applied pressure to the lithosphere over a time step",
}
"lithosphere_surface__elevation_increment":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "The change in elevation of the top of the lithosphere (the land surface) in one timestep",
} +
V
"plant__age":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "Years",
"mapping": "cell",
"doc": "Age of plant",
}
"plant__live_index":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "None",
"mapping": "cell",
"doc": "1 - vegetation__cumulative_water_stress",
}
"vegetation__cumulative_water_stress":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "None",
"mapping": "cell",
"doc": "cumulative vegetation__water_stress over the growing season",
}
"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",
} +
P
"radiation__incoming_shortwave_flux":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "W/m^2",
"mapping": "cell",
"doc": "total incident shortwave radiation over the time step",
}
"radiation__net_flux":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "W/m^2",
"mapping": "cell",
"doc": "net total radiation over the time step",
}
"radiation__net_longwave_flux":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "W/m^2",
"mapping": "cell",
"doc": "net incident longwave radiation over the time step",
}
"radiation__net_shortwave_flux":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "W/m^2",
"mapping": "cell",
"doc": "net incident shortwave radiation over the time step",
}
"radiation__ratio_to_flat_surface":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "None",
"mapping": "cell",
"doc": "ratio of total incident shortwave radiation on sloped surface to flat surface",
}
"surface__potential_evapotranspiration_rate":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "mm",
"mapping": "cell",
"doc": "potential sum of evaporation and potential transpiration",
} +
R
"radiation__incoming_shortwave_flux":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "W/m^2",
"mapping": "cell",
"doc": "total incident shortwave radiation over the time step",
}
"radiation__net_shortwave_flux":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "W/m^2",
"mapping": "cell",
"doc": "net incident shortwave radiation over the time step",
}
"radiation__ratio_to_flat_surface":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "None",
"mapping": "cell",
"doc": "ratio of total incident shortwave radiation on sloped surface to flat surface",
}
"topographic__elevation":
{
"dtype": float,
"intent": "in",
"optional": False,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
} +
S
"rainfall__flux":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "mm/hr",
"mapping": "node",
"doc": "Depth of water delivered per unit time in each storm",
}
"rainfall__total_depth_per_year":
{
"dtype": float,
"intent": "out",
"optional": False,
"units": "mm/yr",
"mapping": "node",
"doc": "Depth of water delivered in total in each model year",
}
"topographic__elevation":
{
"dtype": float,
"intent": "in",
"optional": True,
"units": "m",
"mapping": "node",
"doc": "Land surface topographic elevation",
} +
"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",
} +
O
* Calculation of snowmelt using the surface energy balance or a temperature index/enhanced temperature index method
* Calculation of evapotranspiration for snow-free surfaces using the FAO Penman-Monteith method
+
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
+
I
- output_raster: rasterized change detection data from .las
- acc_d8: flow accumulation raster
- fdir_d8: flow direction raster
- output_shapefile_path: query point shapefile
- output_shapefile: buffered flow path shapefile
- investigation_polygons_shapefile: investigation polygon shapefile (first generated, then populated with volume and geomorphometric data under the same name) +
A
B
C
F
-- +
I
M
-- +
S
-- +
E
F
S
W
B
C
S
T
F
C
F
I
A
-- +
-- +
B
D
-- +
F
-- +
G
-- +
R
-- +
S
-- +
-- +
W
-- +
Q
R
D
-- +
L
U
-- +
A
L
-- +
F
C
B
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. +