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Use of Multi-Model Super-Ensembles in Hydrology Lauren Hay George Leavesley Martyn Clark * Steven Markstrom Roland Viger U.S. Geological Survey Water Resources.

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Presentation on theme: "Use of Multi-Model Super-Ensembles in Hydrology Lauren Hay George Leavesley Martyn Clark * Steven Markstrom Roland Viger U.S. Geological Survey Water Resources."— Presentation transcript:

1 Use of Multi-Model Super-Ensembles in Hydrology Lauren Hay George Leavesley Martyn Clark * Steven Markstrom Roland Viger U.S. Geological Survey Water Resources Discipline National Research Program * University of Colorado - Boulder

2 Hydrologic Simulation Inputs – Time series data Precipitation, Minimum + Maximum Temperature – Parameters (static information) Spatial characteristics Non-spatial characteristics Modeling Software

3 Sources of Error State of the system: observed != simulated Error in: – Inputs Time series data Parameters – Modeling Software

4 Optimization of Model Standard technique: – adjustment of parameters Spatial characteristics Non-spatial characteristics – “Fitting” simulated hydrograph to the observed hydrograph

5 Optimization of Model Standard technique: – adjustment of parameters Spatial characteristics Non-spatial characteristics – “Fitting” simulated hydrograph to the observed hydrograph Ignores numerous other sources of error!

6 Sources of Error Inputs – Time series data Weather Stations

7 Sources of Error Inputs – Time series data Weather Stations –Measurement inaccuracy –Measurement bias –Measurement drift

8 Sources of Error Inputs – Time series data Weather Stations –Measurement inaccuracy –Measurement bias –Measurement drift Global or Regional Climate Model inputs

9 Sources of Error Inputs – Time series data Weather Stations –Measurement inaccuracy –Measurement bias –Measurement drift Global or Regional Climate Model inputs –Model accuracy (timing, volume, extremes) –Spatial scale –Temporal scale

10 Sources of Error Inputs – Time series data Weather Stations –Measurement inaccuracy –Measurement bias –Measurement drift Global or Regional Climate Model inputs –Model accuracy (timing, volume, extremes) –Spatial scale –Temporal scale Representation & Distribution –Does this data describe what’s “hitting the ground”?

11 Sources of Error Inputs – Time series data – Parameters Spatial characteristics

12 Sources of Error Inputs – Time series data – Parameters Spatial characteristics –Quality of GIS layers –Quality of algorithms –Quality of GIS delineation techniques

13 Sources of Error Inputs – Time series data – Parameters Spatial characteristics –Quality of GIS layers (is my soil info accurate enough?) –Quality of algorithms (is my GIS using my soils data correctly?) –Quality of GIS delineation techniques (are my model’s geographic feature concepts appropriately represented in the GIS?)

14 Sources of Error Inputs – Time series data – Parameters Spatial characteristics Non-spatial characteristics

15 Sources of Error Inputs – Time series data – Parameters Spatial characteristics Non-spatial characteristics –adjustment factors for Time series data coefficients for measurement error & bias correction distribution of climate data to land surface units  Modeling Response Units (MRUs)

16 Sources of Error Inputs Modeling Software

17 Sources of Error Inputs Modeling Software – Model concepts valid? – In setting of the application area? – Are selected processes successfully integrated?

18 Sources of Error Inputs Modeling Software Optimization technique – “fitting” the simulated hydrograph to the observed

19 Sources of Error Inputs Modeling Software Optimization technique – “fitting” the simulated hydrograph to the observed How is this measured? Is chosen statistic appropriate? Is a single statistic appropriate? Is this statistics appropriate for the entire cycle of hydrologic response?

20 Optimization of Model Standard technique: – adjustment of parameters Based on single statistic over entire period

21 Optimization of Model Standard technique: – adjustment of parameters Based on single statistic over entire period Seems incomplete!

22 Super-Ensemble Study Joint effort: – USGS – University of Colorado – Boulder Funded by: – NOAA – University of Colorado – USGS (barely)

23 Super-Ensemble Study: purpose Systematically evaluate alternative components for hydrologic modeling Develop optimized modeling configurations Produce map-based database of configurations to support field staff

24 Super-Ensemble Study: approach Specify approximately 15 different model permutations Select 2 watersheds from each Hydrologic Landscape Unit Develop input climate time series data Automate delineation & parameterization of geographic features Automate Sensitivity & Optimization Analyses

25 Super-Ensemble Study: tools Modular Modeling System (MMS) Climate processing methods GIS Weasel MOGSA & MOCOM – Multi-object sensitivity and optimization tools – University of Arizona

26 Super Ensemble Study: MMS PROCEDURESPROCEDURES # Modules in MMS X X X Input Data Climate Processing Solar Radiation Potential Evapotranspiration Snow Soil Subsurface Groundwater X X X X X X X X

27 Super Ensemble Study: MMS

28

29 Climate Processing Methods Produces time series values for each MRU Basin Average Inverse Distance Nearest Neighbor Thiessen Polygons XYZ Local Polynomial Regression Artificial Neural Networks

30 Basin Selection 2 basins from each HLU approximately 70 for first iteration Each basin part of Hydrologic Climate Data Network (HCDN) Drainage area > 50 km 2 < 3000 km 2

31 Land surface form Climate geology Hydrologic Landscape Units (HLUs)

32

33 Basin Selection

34

35 GIS Weasel Simplifies the creation of spatial information for modeling Provides tools to: Delineate Parameterize relevant spatial features

36 GIS Weasel Still have to insert a nice plug for da weasel…

37 GIS Weasel: Example Delineation Methodology

38 “Uncalibrated” Watershed Model METHODOLOGY Basin Setup Optimize Volume Optimize Timing

39 Basin Setup Optimize Volume Optimize Timing “Uncalibrated” Watershed Model METHODOLOGY Basin Setup 1.Data set compilation (temperature, precipitation, DEM, Q) 2.Basin delineation 3.GIS Weasel 4.XYZ parameterization

40 Basin Setup Optimize Volume Optimize Timing METHODOLOGY Basin Setup “Uncalibrated” Watershed Model Identify and calibrate the ET parameters by comparing “observed” and simulated monthly mean PET out of hydrologic model Get a Water Balance Calibrate ET and climate station choice August Monthly Mean PE

41 “Uncalibrated” Watershed Model METHODOLOGY Basin Setup Optimize Volume Optimize Timing Get a Water Balance Calibrate ET and climate station choice Find ‘best’ climate station sets

42 METHODOLOGY Uncalibrated Watershed Model “Uncalibrated” Watershed Model METHODOLOGY Basin Setup Optimize Volume Optimize Timing Developed at U. of AZ: MOGSA MO MOGSA – Multi Objective G Generalized S Sensitivity A Analysis Determines parameter sensitivity Identify and optimize sensitive parameters

43 METHODOLOGY Uncalibrated Watershed Model “Uncalibrated” Watershed Model METHODOLOGY Basin Setup Optimize Volume Optimize Timing Developed at U. of AZ: MOGSA MO MOGSA – Multi Objective G Generalized S Sensitivity A Analysis Determines parameter sensitivity Developed at U. of AZ: MOCOM MO MOCOM – Multi-Objective COM COMplex Evolution Solves the multi-objective optimization problem Identify and optimize sensitive parameters

44 FD: Driven FQ: Quick FS: Slow FD FS FQ FS Multi-Objective Peak/Timing Quick recession Baseflow (See Boyle et al., WRR, 2000)

45 Anticipated Products Linking of physical processes – Atmospheric – Watershed – Two-way interaction (eventually) Development of Super-ensemble approach Physically-based watershed models that need limited interactive calibration

46 Anticipated Products Regionalization (spatial maps) of: Climate: –recommended sources variables –processing methods –parameters Recommendations for place-specific model selection/configuration Pareto sets of optimized parameters Confidence and error figures

47 Limitations Study deals with limited modeling question – Volume & timing of streamflow – Watershed scale (50-3000 km2) – Daily time step Limited number of physical process algorithms tested Limited number of watersheds featured – Automation will enable broader (nationwide) application

48 Timeline Dare we make these predictions?

49 Work Completed Climate processing – 4 of 7 methods implemented – Station observations selected for all test basins Records clean – Regional and Global Climate Model outputs assembled GIS – Delineation of geographic features automated – Parameterization of geographic features automated – Spatial data layers assembled – Processing complete

50 Work Completed Hydrologic science modules assembled MOGSA & MOCOM established

51 Contact Information Staff – George Leavesley (project chief) – Lauren Hay – Steve Markstrom – Roland Viger – Martyn Clark URLs – http://wwwbrr.cr.usgs.gov/mms http://wwwbrr.cr.usgs.gov/mms – http://wwwbrr.cr.usgs.gov/weasel http://wwwbrr.cr.usgs.gov/weasel george@usgs.gov lhay@usgs.gov markstro@usgs.gov rviger@usgs.gov clark@vorticity.colorado.edu

52 Thank You

53 Climate Processing Need to be able to distribute: From: stations grid points To: individual Modeling Response Unit (MRU)

54 Multiple Linear Regression (MLR) equations – Developed for: Precipitation Temperature, Maximum Temperature, Minimum – Based on: X Y Z – Monthly – Explains variation in observation across stations Climate Processing: XYZ overview Same relationship between stations and MRUs (use MRU X,Y,Z in MLR)

55 Climate Processing: Statistical Downscaling (SDS) overview Output from Global Climate Model (GCM) – National Center for Environmental Prediction (NCEP) model Averaged to a point (e.g. basin centroid) Distributed to MRUs – XYZ methodology

56 Climate Processing: Dynamical Downscaling (DDS) overview Uses Regional Climate Model – RegCM2 – Seeded with NCEP output Averaged to a point (e.g. basin centroid) Distributed to MRUs – XYZ methodology

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