In determining the consumptive use for the Delta, several research groups have been invited to estimate evapotranspiration estimates.
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CalSIMETAW - Department of Water Resources [DWR], Morteza Orang): Estimates daily soil water balance to determine ETc and ETaw for use in California Water Plan Update.
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DETAW - DWR, Tariq Kadir: Computerized ground surface water balance model for 168 subareas within the California Delta.
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UCD-METRIC - UCDavis, Josué Medellín-Azuara: estimates ET based on energy balance and the partition of sensible and latent heat flux using mostly Landsat satellite data; with the internal calibration of the sensible heat computation using the ground-based reference ET.
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ITRC - CalPoly, Dan Howes: modifies METRIC by using a semi-automated internal calibration and replacing the alfafa reference ET with grass reference ET.
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SIMS - NASA Ames, Forrest Melton: utilizes the NASA Terrestrial Observation and Prediction System (TOPS) to integrate satellite observations and meteorological observations to map basal crop coefficients and evapotranspiration.
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UCD-PT - UCDavis, Yufang Jin: the Priestley Taylor ET approach uses the optimized semi-empirical Priestley-Taylor (PT) equations to estimate ET; net radiation, ground heat flux, and the PT coefficients are derived from MODIS and Landsat satellite data.
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DisALEXI - US Department of Agriculture-ARS, Martha Anderson: uses thermal satellite data based on the two-source Atmosphere-Land Exchange Inverse (ALEXI) model. Higher resolution ET estimate is obtained through a spatial disaggregation technique using MODIS and Landsat data.
Product | CalSIMETAW | UCD-METRIC | ITRC | SIMS | UCD-PT | DETAW | DisALEXI |
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ET | M/D | M | M | M | M | M/D | M |
M=Monthly; D=Daily |
Product | CalSIMETAW | UCD-METRIC | ITRC | SIMS | UCD-PT | DETAW | DisALEXI |
---|---|---|---|---|---|---|---|
Weather | D | I/D | I/D | D | |||
ETo | D | D | I/D | ||||
ETr | D | I/D | I/D | ||||
Landcover | D | M | |||||
Landsat8 | I | I | I | I | I | ||
MODIS | I | I | |||||
GOES | I | ||||||
[DEM] | I | I | I | I | I | ||
where M=Monthly; D=Daily |
Product | CalSIMETAW | UCD-METRIC | ITRC | SIMS | UCD-PT | DETAW | DisALEXI |
---|---|---|---|---|---|---|---|
ET | I | I | I | I | I | I | |
ETo | D/M | I | I | I | I | D/M | I |
ETr | I | I | I | I | |||
Kc | D/M | I | I | I | I | D | I |
Kcr | I | I | I | ||||
Rn | I | I | I | ||||
G | I | I | I | ||||
H | I | I | I | ||||
masks | I | I | I | ||||
where I=Instanteous; M=Monthly; D=Daily |
masks are any masks that limit the calculation of instantaneous ET.
This project contains the suggested boundaries used for the ssj-delta-cu project summary. This includes the delta service area boundary, as well as suggested rasters boundaries for input and output project data.
<iframe src="https://www.google.com/maps/d/u/0/embed?mid=zDpfBkZvP6Yk.kvF3ZvPShMdE" width="640" height="480"></iframe>The suggested region for gridded data uses the California Equal Area projection
EPSG:3310 with the lower left
corner ll=-164000 -44000
and the upper right corner ur=-108000 68000
These boundaries are coincident with DWR's Cal-SIMETAW planning grid, which has pixel size of 4km, as well as the Spatial CIMIS program, with a pixel size of 2km.
For higher resolution imagery, we suggest the following potential resolutions, all of which share boundaries at the pixel level:
pixel (m) | x | y | total |
---|---|---|---|
4000 | 14 | 28 | 392 |
2000 | 28 | 56 | 1568 |
1000 | 56 | 112 | 6272 |
500 | 112 | 224 | 25088 |
250 | 224 | 448 | 100352 |
125 | 448 | 896 | 401408 |
25 | 2240 | 4480 | 10035200 |
For example, our landsat imagery will be delivered at 25m (cubic spline interpolated). However any resolution with an integral number of pixels in the region is acceptable.
- 12 band geotiff raster
- Each band representing month of the water year (Oct -> Sep)
- Average daily ET units in tenths of a mm per day (mm/day * 10) in order to use integer rasters.
Git Large File Storage (LFS) must be used when any file in the repo is > 100 mb. If everything is less than ~50 mb you can just use git to commit the files and push the changes to the appropriate repository. Git LFS is a command line extension for efficiently dealing with large files. It replaces large files with text pointers inside Git, while storing the file contents on a github.com. Git LFS should be used for files that don't change often as each updated file counts towards the data limit for the repository.
TIP: make sure to compress rasters before adding the files to git lfs. This will significantly shrink the size of the commit .
- Set up Git LFS
- Configure git lfs to track files
- Commit and push changes to appropriate repo
A second option if you are unable to set up git with lfs enabled is to upload the files to the project's private folder on box. Access to the upload folder is limited (@andybell, @josue-medellin, @jessejanko). We will add the files to the appropriate repository.
ssj-delta-cu private folder upload
version | milestone |
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v1-0-0 | inital assets from inital report (ie September 2016). Only 2015 water year. |
v1-0-1 | any changes with uploading/converting rasters |
v1-1-0 | any modifications recieved from groups |
v2-0-0 | Data received from groups on April 28, 2017 |
v3-0-0 | Data revisions after review |