1. �End-to-End Workflows for Coupled Climate and Hydrological Modeling��Edwin Sumargo (University of Illinois at Urbana-Champaign)� Sylvia Murphy (NOAA/CIRES) �Kathy Saint (SGI Inc)�����
2. Outline Ongoing Project Objective
System Description
Project Phases
Internship Goals
CAM to SWAT Conversion
Downscaling
Soil and Water Assessment Tool (SWAT)
Remaining Tasks
Summary
3. Ongoing Project Objective
4. System Description
5. Project Phases
6. Internship Goals Determine the variable and unit conversions necessary to couple CAM to SWAT
Investigate downscaling methods and determine under which
conditions to use each
Investigate C/C++ nearest neighbor algorithms
Install SWAT on a public PC at NOAA
Investigate SWAT configuration options
Create graphics of SWAT output
Begin the calibration process for SWAT
7. CAM to SWAT Conversion SWAT reference: (Neitsch et al., 2004)
CAM reference: (McCaa et al., 2004)
Variables needed to be converted:
Air Temperature
Solar Radiation
Precipitation
Relative Humidity
Wind Speed
8. Downscaling Downscaling methods were investigated (Fowler et al., 2007)
A method needed to be determined for both the current and future system
“Downscaling climate data is a strategy for generating locally relevant data from Global Circulation Models (GCMs). The overarching strategy is to connect global scale predictions and regional dynamics to generate regionally specific forecasts” (http://www.climate-decisions.org).
3 fundamental downscaling methods:
Dynamical Downscaling (DD)
Statistical Downscaling (SD)
Nearest Neighbor Interpolation (NNI): the simplest case
9. Dynamical Downscaling A downscaling method where a higher resolution climate model is embedded within a GCM (Fowler et al., 2007).
Uses regional climate or limited-area models
Typically resolved at approximately 0.5° latitude and longitude scale and parameterize physical atmospheric processes.
Advantages:
Performs better at regions where topographic effects are prominent
Superior for which convective precipitation is involved
Disadvantages:
Computationally very intensive
Strongly depends on GCM boundary forcing
Has limited number of scenario ensembles available
10. Statistical Downscaling A downscaling method that establishes empirical relationships between GCM-resolution climate variables and local climate (Fowler et al., 2007).
Advantages:
More efficient than dynamical downscaling
More suitable in handling the extremes, e.g. of temperature
Performs better at higher altitude, mainly with continental climate
Disadvantages:
Underestimates variance
Excludes climate feedbacks
Skill is affected by domain size, climatic region, and season
11. Nearest Neighbor Interpolation Nearest Neighbor Interpolation was determined to be the most appropriate downscaling method for the current system.
This is because there is only one atmospheric grid point in the hydrological domain.
Nearest neighbor interpolation calculates the distance between the points on the grid and the center of the hydrological domain.
We adapted this calculation to the sphere using the Haversine formula (http://www.movable-type.co.uk/scripts/latlong.html).
A future phase of the system will involve more than one atmospheric grid point per hydrological domain.
It is anticipated that statistical downscaling will be used.
12. SWAT SWAT is a river basin scale model developed to quantify the impact of land management practices in large, complex watersheds (http://swatmodel.tamu.edu).
Runs on Windows platform
Configuration of SWAT is easier with GIS software
MWSwat is a free GIS interface to SWAT
13. Setup and Run Domain: Lake Fork Creek watershed near Quitman, TX
Default test basin on SWAT2005
Setup and ran 20-year simulation (1990-2009)
SWAT outputs data as ASCII texts
Developed plots of the output
14. Calibration Each SWAT basin must be calibrated, including the Lake Fork test basin that comes with SWAT.
Downloaded the observed time series from USGS website
Data are daily mean water discharges (ft3/s) at Lake Fork Creek watershed
Reviewed calibration techniques
Attempted modification of input parameters
Reran to calibrate
Recalibrated (as needed)
15. Remaining Tasks Work on MWSwat to configure the output files of SWAT
Continue SWAT calibration
16. Summary To couple an atmospheric model and a hydrological model, careful unit conversions are needed to connect data flows. To determine the best downscaling method for the project also required thorough investigation. Running and calibrating SWAT were crucial to complete Phase 4 of an end-to-end workflow.
17. Questions Earth System Curator: http://earthsystemcurator.org
ESMF: http://earthsystemmodeling.org
OpenMI: http://www.openmi.org
CAM: http://www.ccsm.ucar.edu/models/ccsm4.0/cam
SWAT: http://swatmodel.tamu.edu
MWSwat: http://www.waterbase.org/download_mwswat.html
sumargo1@illinois.edu
sylvia.murphy@noaa.gov
ksaint@sgi.com
Reference: Fowler, H., Blenkinsop, S., & Tebaldi, C. (2007). Linking climate change
modelling to impacts studies. International Journal of Climatology, 27, 1547-1578.
18. CAM to SWAT Conversion SWAT reference: (Neitsch et al., 2004)
CAM reference: (McCaa et al., 2004)
1. Air Temperature
SWAT requires air temperature at surface (TMPSIM) in °C. The variable in CAM is TS in K.
TMPSIM °C = TS K – 273.15
2. Solar Radiation
SWAT requires daily solar radiation incident on surface (SLRSIM) in MJ m-2. The variable in CAM is SOLIN in W m-2.
SLRSIM MJ m-2 day-1 = SOLIN J s-1 m-2 * 86400 s day-1 * 10-6 MJ J-1
19. CAM to SWAT Conversion 3. Precipitation
SWAT requires total liquid precipitation (PCPSIM) in mm(H2O) day-1. The variables in CAM are:
PRECC = Convective Precipitation Rate (m s-1)
PRECL = Large Scale (stable) Precipitation Rate (m s-1)
PRECT = Total Precipitation Rate (m s-1) = PRECC + PRECL
PCPSIM mm day-1 = PRECT m s-1 * 86400 s day-1 * 1000 mm
m-1, if PRECT is available.
PCPSIM mm day-1 = (PRECC m s-1 + PRECL m s-1) * 86400 s day-1 * 1000 mm m-1, if PRECT is not on the file.
20. CAM to SWAT Conversion 4. Relative Humidity
SWAT requires relative humidity (RHSIM) in decimal fraction. The variable in CAM is RELHUM in percent.
RHSIM (decimal fraction) =
5. Wind Speed
SWAT requires (horizontal) wind speed (WNDSIM) in m s-1. The variables in CAM are WSPEED in m s-1.
UBOT = zonal wind speed at the bottom of the atmospheric layer (m s-1)
VBOT = meridional wind speed at the bottom of the atmospheric layer (m s-1) = horizontal total wind speed (m s-1)
WNDSIM m s-1 = WSPEED m s-1
