1. California Water Demand Scenarios David Groves
Pardee RAND Graduate School
Scott Matyac and Tom Hawkins
Department of Water Resources
* * *
California Water Plan Update Advisory Committee Meeting
January 20, 2005
2. Purpose of Analysis Provide preliminary quantitative estimates of 2004 Water Plan narrative water demand scenarios (not FORMAL estimates)
Advance conceptual thinking on using a scenario approach for future Water Plans
Create a scenario estimator for other non-Water Plan related analyses
3. History of Collaboration Water Plan Staff and Advisory Committee embraced scenario approach for Water Plan phased work plan
Concurrently, RAND began a scenario-based look at long-term water resources planning in California
RAND and Water Plan staff now collaborating to create water demand scenario generator and quantify narrative scenarios
RAND expects to continue to use and develop this model for further analyses
4. Approach 1) Create model to generate plausible average 2030 water demand scenarios
Simple, understandable, fast running, and easily modifiable
Ability to mimic/incorporate results of detailed models
Specify scenarios through unique parameter values
2) Select parameter values congruent to narrative descriptions
3) Quantify, evaluate, and interpret projected water demand
Test for plausibility
Identify aspects needing further study
Gain insight
4) Follow-up with more detailed analysis
5. A Few Words About Scenarios Scenarios are NOT predictions
No one scenario is expected to predict what will occur
Instead, they reflect multiple plausible views of the future
Scenarios are useful when
Ability to predict is low due to large uncertainties
Individual outcomes are important
Desire to avoid low probability, negative events
Scenarios help analysts and decision-makers:
Evaluate uncertain potential outcomes
Generate new ideas for successful policies
Scenarios should be evaluated together as a package
6. The Water Demand Scenario Estimator Three Modules
Urban
Agricultural
Environmental
Annual time step from 2000 to 2030
Disaggregated by Hydrologic Region
7. Urban Water Demand Estimates based upon projections of water use by:
Households
Economic activity (based on employment)
Public activities (based on population)
Losses and intentional groundwater recharge
Water use per demand unit varies
Water price, income, household size, naturally occurring conservation, and efficiency adoption
Initialized using year 2000 data
Can use detailed models (e.g. IWR-MAIN) for calibration
8. Urban Water Demand Details Demand Units
Households
Single- and multi-family
Interior and exterior
Commercial Employees
Industrial Employees
Institutional Use (per capita)
9. Population Changes Drive�Housing and Employment SF and MF houses a function of:
Population
Fraction of population housed
Share of SF houses
Household Size
Commercial & Industrial employees a function of:
Population
Employment rate
Share of commercial versus industrial jobs
10. Agricultural Water Demand Estimates based on:
Projected future agricultural land use
Changes in crop water needs
Changes in water application technology and practices
Uses results of other models for calibration
ETAW (initializing data)
CALAG (when ready)
11. Irrigation Demand Calculated by Estimating Crop Demand IU = State-wide irrigation water use
ICA = Irrigated crop area
Irrigated Land Area + Multi-cropped Area
AW = Required applied water per area by crop
12. Irrigation demand changes over time IU changes in response to changes in:
Irrigated land area (ILA)
Multi-cropped area (MA)
Applied Water (AW) – improved varieties of crops, better irrigation methods or technology, change in weather
Cropping pattern – reflected in changing ICA by crop
13. Rule-based Procedure for�Agricultural Land Use Changes Estimate state-wide changes
Irrigated land area
Multi-cropped area
Irrigated cropped area
Apportion state-wide changes to hydrologic regions
Some regions more apt to absorb changes than others
1998 CWP land-use forecasts for low change regions
Estimate crop mix changes for each hydrologic region
Low value crops reduced more than high value crops
Ratio of area multi-cropped over area with multi-cropping potential must remain within a specified range
14. Environmental Demand Very rudimentary procedure
Based on year 2000 unmet needs (Environmental Defense)
More complete treatment would incorporate variable hydrology
15. Water Plan Narrative Scenarios
16. No single method for choosing numerical values for parameters There is no “correct” scenario
Other modeling studies inform quantification
Ex: DOF demographic projections
Important to quantify drivers independently of scenario results
Check intermediate results for plausibility
17. Scenario Specification (Urban 1)
18. Scenario Specification (Urban 2)
19. Scenario Specification (Agriculture)
20. Statewide Results Increase in urban demand, decrease in agricultural demand
Net demand differs by scenario
Cannot offset state-wide urban increases with state-wide agricultural decreases!!!
Ag water use reduction is largest in Current Trends due to specification of agricultural land use in narratives.
21. Results (Illustrative and Preliminary)�by Hydrologic Region Model initially developed to evaluate state-wide trends
Disaggregating by HR difficult due to unique regional characteristics
Unique land use thresholds
Different economic forces
Ideally, each HR would have own set of rules to constrain scenarios …. work in progress
22. North Coast and North Lahontan NC: Ag demand reduction due to efficiency improvements
NL: Ag increases due to increased irrigated land area
23. San Francisco and Central Coast SF: Urban water demand increase [4% -> 32%]
CC: Ag water use reductions due to reduction in irrigated land area. No changes in multi-cropping
24. Sacramento River Urban water use increases greater than reductions in agricultural water use
Large increase in multi-cropping leads to increases in ICA under all scenarios
25. San Joaquin River Large agricultural demand reductions in Current Trends and Resource Efficient scenarios
Large urban demand increases
26. Tulare Lake Similar to San Joaquin without environmental water demand increases
27. South Coast Agricultural land reduction drives reductions in agricultural water use
Urban water demand increases overwhelm agricultural demand decreases except in Resource Efficient scenario
28. Colorado River Large decreases in agriculture offset urban increases in Current Trends and Resource Intensive scenarios
Increase in multi-cropping ranges from 20%-26%
29. South Lahontan Urban demand increases are greater than agricultural demand reductions
30. Closing Remarks Interpretation of Scenarios
NOT forecasts
Will be evaluated using more detailed analyses and models for 2008 Water Plan
Additional scenarios can easily be generated and evaluated (stay tuned…)
Improvements to scenario generator
Introduce interannual variability due to weather
Couple to water supply and management scenarios
Reflect annual cycle
Interannual hydrologic variability
