Difference between revisions of "Alternate Run Modes:Inset Models"
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− | = Inset Models = | + | == Inset Models == |
+ | |||
+ | GSSHA is able to share data between individual models. The basic process goes like this: | ||
+ | # Create the Tier 1 (larger) model | ||
+ | # Create the Tier 2 (inset) model | ||
+ | # In the Tier 1 model project file, add the XY boundary output cards to refer to the Tier 2 model mask file and output data sets | ||
+ | # In the Tier 2 model project file, add the XY boundary input cards to refer to the new data sets from the Tier 1 model | ||
+ | # Run the Tier 1 model | ||
+ | # Run the Tier 2 model | ||
+ | |||
+ | XY Boundary Output Cards – used in the Tier 1 model: | ||
+ | {| class="wikitable" style="margin:auto" | ||
+ | |+ | ||
+ | !CARD !!Example Parameter | ||
+ | |- | ||
+ | |XYBDYOUTPUT_MASK ||"..\Tier2Model\Tier2Model.msk" | ||
+ | |- | ||
+ | |XYBDYOUTPUT_OVDEP ||"..\Tier2Model\Tier1Model.ovdep.ts" | ||
+ | |- | ||
+ | |XYBDYOUTPUT_STFLOW ||"..\Tier2Model\Tier1Model.sthyd.ts" | ||
+ | |- | ||
+ | |XYBDYOUTPUT_GWHEAD ||"..\Tier2Model\Tier1Model.gwhead.ts" | ||
+ | |} | ||
+ | |||
+ | XY Boundary Input Cards - used in the Tier 2 model: | ||
+ | {| class="wikitable" style="margin:auto" | ||
+ | |+ | ||
+ | !CARD !!Example Parameter | ||
+ | |- | ||
+ | |XYBDYINPUT_OVDEP ||"Tier1Model.ovdep.ts" | ||
+ | |- | ||
+ | |XYBDYINPUT_STFLOW ||"Tier1Model.sthyd.ts" | ||
+ | |- | ||
+ | |XYBDYINPUT_GWHEAD ||"Tier1Model.gwhead.ts" | ||
+ | |} | ||
+ | |||
+ | |||
+ | |||
+ | The Tier 1 GSSHA simulation will read the Tier 2 mask file and determine where the edges of the Tier 2 model overlap the Tier 1 grid and also where they intersect the Tier 1 stream network. The Tier 1 model will output data for the overland depth (XYBDYOUTPUT_OVDEP), the stream flow (XYBDYOUTPUT_STFLOW), and the groundwater head (XYBDYOUTPUT_GWHEAD) at the edge locations (all Tier 1 cells with Tier 2 edge cells, or nearest Tier 1 stream link/node as it crosses the Tier 2 grid edge) it identified. | ||
− | |||
<noinclude> | <noinclude> | ||
{{Nav|Nav18}} | {{Nav|Nav18}} | ||
</noinclude> | </noinclude> |
Latest revision as of 22:25, 6 April 2023
Inset Models
GSSHA is able to share data between individual models. The basic process goes like this:
- Create the Tier 1 (larger) model
- Create the Tier 2 (inset) model
- In the Tier 1 model project file, add the XY boundary output cards to refer to the Tier 2 model mask file and output data sets
- In the Tier 2 model project file, add the XY boundary input cards to refer to the new data sets from the Tier 1 model
- Run the Tier 1 model
- Run the Tier 2 model
XY Boundary Output Cards – used in the Tier 1 model:
CARD | Example Parameter |
---|---|
XYBDYOUTPUT_MASK | "..\Tier2Model\Tier2Model.msk" |
XYBDYOUTPUT_OVDEP | "..\Tier2Model\Tier1Model.ovdep.ts" |
XYBDYOUTPUT_STFLOW | "..\Tier2Model\Tier1Model.sthyd.ts" |
XYBDYOUTPUT_GWHEAD | "..\Tier2Model\Tier1Model.gwhead.ts" |
XY Boundary Input Cards - used in the Tier 2 model:
CARD | Example Parameter |
---|---|
XYBDYINPUT_OVDEP | "Tier1Model.ovdep.ts" |
XYBDYINPUT_STFLOW | "Tier1Model.sthyd.ts" |
XYBDYINPUT_GWHEAD | "Tier1Model.gwhead.ts" |
The Tier 1 GSSHA simulation will read the Tier 2 mask file and determine where the edges of the Tier 2 model overlap the Tier 1 grid and also where they intersect the Tier 1 stream network. The Tier 1 model will output data for the overland depth (XYBDYOUTPUT_OVDEP), the stream flow (XYBDYOUTPUT_STFLOW), and the groundwater head (XYBDYOUTPUT_GWHEAD) at the edge locations (all Tier 1 cells with Tier 2 edge cells, or nearest Tier 1 stream link/node as it crosses the Tier 2 grid edge) it identified.
GSSHA User's Manual
- 18 Alternate Run Modes
- 18.1 MPI and OpenMP Parallelization
- 18.2 Simulation Setup for Alternate Run Modes
- 18.3 Batch Mode Runs
- 18.4 Automated Calibration with Shuffled Complex Evolution
- 18.5 Monte Carlo Runs
- 18.6 ERDC Automated Model Calibration Software
- 18.6.1 Efficient Local Search
- 18.6.2 Multistart
- 18.6.3 Trajectory Repulsion
- 18.6.4 Effective and Efficient Stochastic Global Optimization
- 18.7 Inset Models