Transcript Document

Forecasting Streamflow with the UW
Hydrometeorological Forecast
System
Ed Maurer
Photos from: www.metrokc.gov
Department of Atmospheric Sciences, University of Washington
Pacific Northwest Weather Workshop
March 8, 2003
UW Hydromet System and Water
Resource Time Scales
Weather: floods,
drainage, operations
Seasonal/Interannual:
water supply planning,
droughts
Climate: climate change,
urbanization
Ref: A Plan for a New Science Initiative
on the Global Water Cycle, www.usgcrp.gov
Temporal and Spatial Scales of
Hydrologic Variability
Accurate representation
of spatial and temporal
variability in:
•Precipitation
•Land surface hydrology
is essential for
simulating hydrological
response at this scale
Ref: A Plan for a New Science Initiative
on the Global Water Cycle, www.usgcrp.gov
MM5-DHSVM Streamflow Forecast
System
UW Real-time
MM5
DHSVM
Distributed-Hydrology-Soil-Vegetation
Model
Completely automated
In use since WY 1998
Streamflow and
other forecasts
For details: Westrick, K.J., P. Storck, and C.F. Mass,
Description and Evaluation of a
Hydrometeorological Forecast System for
Mountainous Watersheds, Weather and
Forecasting 17: 250-262, 2002.
Penn State/NCAR Mesoscale Model MM5
Used throughout the world for
both research and
operational forecasting
48-hour (and some 72-hour
and longer) forecasts run
twice daily at the
University of Washington
High-resolution model (4-km)
capable of capturing the
complex orography of the
region, including lee
shading and windward
precipitation enhancement
FOR MORE INFO...
http://www.atmos.washington.edu/mm5rt/
DHSVM land surface hydrology model
•Physically-based,
distributed model
•Solves a water
balance at each
grid cell at each
time step
•Horizontal scales
typically 30m to
150m
•Designed for and
extensively
tested in complex
terrain
Details on DHSVM at:
http://www.hydro.washington.edu/
DHSVM Calibration
Calibration at 2 sites in Snohomish
River Basin
• Used all available meteorological
observations (50sites), 1987-1991
• Used flow observations at two USGS
gauges:
–
–
Snoqualmie R. at Carnation
Skykomish R. near Gold Bar
Snoqualmie R. at Carnation
Peaks flows and average water
balance are well simulated by
DHSVM when forced by observed
meteorology
UW Hydromet Domain - 2003
26 basins
~60 USGS Gauge
Locations
48,896 km2
2,173,155 pixels
DHSVM @ 150 m
resolution
MM5 @ 4 & 12 km
Web Site for Forecast Dissemination
•Automatically
updated twice
daily
•Graphic display
indicates
forecasted flood
status
•Click through to:
- Hydrographs
- Snow state
(maps and
points)
- Point weather
forecasts
Performance of Hydromet System
Sauk
Observed
MM5-DHSVM
NWRFC
Snoqualmie
Using the Hydromet system for
MM5 diagnosis
Onecourse,
exceptionally
bad forecast
for
Of,
not all forecasts
were
thebad…
Cedar R., events from January
so
25 to Feb 4, 2003
Second peak:
•Forecast:1200 cfs
•Observed: 3700 cfs
•Flood stages above bankfull
occurred, and were not forecast
Representative Meteorological
Station – Mt. Gardner
Precip
Avg. Precipitation from 1/24 - 2/7:
Observed: 1.0 mm/h
Simulated: 0.7 mm/h
Total difference: ~100 mm
Average Temperature:
Observed: +2.1C
Predicted*: -0.1C
SWE:
Observed: -50 mm
Predicted*: +100 mm
MM5 biases in P and T
combine to produce large
underestimation in runoff
Temp
SWE
Opportunity for Improving UW
Hydromet Forecasts
1 – Precipitation/Temperature Bias Correction
Remove systematic biases in P, T, at land surface
2 – IMPROVE-2
Take advantage of the IMPROVE-2 experiment to
examine the interplay between observation density
and bias correction performance
3 – Initial State Updating
Assimilation of snow and soil moisture information
from an observationally constrained data set.
Snow State Updating with
Observations
Use ground
observations
(SNOTEL sites)
to adjust the
basin snow state
Challenge:
45-50 snow water
observations for 48,000
km2 domain – low density
places high dependence
on interpolation
assumptions
Expansion of Forecast Products
•Probabilistic streamflow
forecasts
-Take advantage of ensemble
MM5 simulations to estimate
uncertainty in forecasts
Source: Grimit and
Eckel, 2003
•Forecasts of slope stability
Probability of failure
Image courtesy of L. Bowling
- DHSVM produces more than just
streamflow
- Soil moistures, slopes in model provide
additional forecasting capabilities
- Investigate landslide hazard forecasting
Summary
• UW Hydrometeorological Forecast System
provides accurate streamflow and snowpack
predictions when forced with accurate
meteorology and when properly initialized
• Improvements in both initialization and
meteorological forecasts are ongoing, by
analyzing current flood events and retrospective
analysis
• The capabilities of the system are being expanded
to include both probabilistic forecasts using
ensembles, and to include landslide hazard
evaluation
Acknowledgments
Current Streamflow Forecasts
•NWRFC provides river flow
and stage forecasts at
strategic points in Puget
Sound region
•Use point forecasts of
precipitation and
temperature
•Streamflow produced by a
lumped parameter
hydrologic model (does not
produce spatially distributed
water balance estimates)
www.nwrfc.noaa.gov
Original Motivation for Developing
UW Hydromet System
• Integrated modeling over a variety of spatial and
temporal scales to examine:
– Regionally consistent modeling of weather and land
surface hydrology, avoid site-specific calibration
– Capture topographically-driven spatial variation in
precipitation, temperature, and wind fields
– Produce experimental streamflow forecasts to
investigate skill in a coupled model setting
• Use hydrometeorological forecasts as a diagnostic
tool for mesoscale atmospheric model