Adjustment of Global Gridded Precipitation for Systematic Bias Jennifer Adam Department of Civil and Environmental Engineering University of Washington.

Slides:

Advertisements

Similar presentations

Improved CanSIPS Initialization from Offline CLASS Simulation and Data Assimilation Aaron Berg CanSISE Workshop.

Advertisements

Developing a Caribbean Climate Interactive Database (CCID) Rainaldo F. Crosbourne, Michael A. Taylor, A. M. D. Amarakoon** CLIMATE STUDIES GROUP MONA Department.

Development of Bias-Corrected Precipitation Database and Climatology for the Arctic Regions Daqing Yang, Principal Investigator Douglas L. Kane, Co-Investigator.

Extension and application of an AMSR global land parameter data record for ecosystem studies Jinyang Du, John S. Kimball, Lucas A. Jones, Youngwook Kim,

Outline Detecting occurrence and quantifying amount of precipitation Sources of errors Reading Assignment: Section 4.1.

Precipitation - Manual gauges - Tipping bucket gauges - Weighing gauges - Calibration of rain gauges - Measuring snow.

Land Surface Processes in Global Climate Models (2)

Dennis P. Lettenmaier Alan F. Hamlet JISAO Center for Science in the Earth System Climate Impacts Group and Department of Civil and Environmental Engineering.

Arctic Land Surface Hydrology: Moving Towards a Synthesis Global Datasets.

Alan F. Hamlet Dennis P. Lettenmaier JISAO Center for Science in the Earth System Climate Impacts Group and Department of Civil and Environmental Engineering.

Advances in Macroscale Hydrology Modeling for the Arctic Drainage Basin Dennis P. Lettenmaier Department of Civil and Environmental Engineering University.

1. Introduction 3. Global-Scale Results 2. Methods and Data Early spring SWE for historic ( ) and future ( ) periods were simulated. Early.

GPCC Global Precipitation Climatology Centre Calculation Of Gridded Precipitation Data for Global Land-Surface Using In Situ Gauge Observations IPWG, Monterey,

Guo-Yue Niu and Zong-Liang Yang The Department of Geological Sciences The University of Texas at Austin Evaluation of snow simulations from CAM2/CLM2.0.

Estimating Continental-Scale Water Balance through Remote Sensing Huilin Gao 1, Dennis P. Lettenmaier 1 Craig Ferguson 2, Eric F. Wood 2 1 Dept. of Civil.

Experimental seasonal hydrologic forecasting for the Western U.S. Dennis P. Lettenmaier Andrew W. Wood, Alan F. Hamlet Climate Impacts Group University.

NWS Calibration Workshop, LMRFC March, 2009 Slide 1 Analysis of Evaporation Basic Calibration Workshop March 10-13, 2009 LMRFC.

Correction Band Correction of Global Precipitation Products for Systematic Bias and Orographic Effects Jennifer C. Adam 1, Dennis P. Lettenmaier.

A Variational Ensemble Streamflow Prediction Assessment Approach for Quantifying Streamflow Forecast Skill Elasticity AGU Fall Meeting December 18, 2014.

Reducing Canada's vulnerability to climate change - ESS J28 Earth Science for National Action on Climate Change Canada Water Accounts AET estimates for.

CIMO Survey National Summaries of Methods and Instruments Related to Solid Precipitation Measurement at Automatic Weather Stations - Very Preliminary results.

Combining CMORPH with Gauge Analysis over

Global Flood and Drought Prediction GEWEX 2005 Meeting, June Role of Modeling in Predictability and Prediction Studies Nathalie Voisin, Dennis P.

Introduction 1. Climate – Variations in temperature and precipitation are now predictable with a reasonable accuracy with lead times of up to a year (

Adjustment of Global Gridded Precipitation for Orographic Effects Jennifer Adam.

Evaluating the variability and budgets of global water cycle components V. Sridhar 1, G. Goteti 2, J. Sheffield 2, J. Adam 1 D.P. Lettenmaier 1, E.F. Wood.

Adjustment of Global Gridded Precipitation for Orographic Effects Jennifer C. Adam 1 Elizabeth A. Clark 1 Dennis P. Lettenmaier 1 Eric F. Wood 2 1.Dept.

Spatial variability of the correction ratio across each of the gauged basins was constructed by developing a relationship between the correction ratio.

Status and Plans of the Global Precipitation Climatology Centre (GPCC) Bruno Rudolf, Tobias Fuchs and Udo Schneider (GPCC) Overview: Introduction to the.

Efficient Methods for Producing Temporally and Topographically Corrected Daily Climatological Data Sets for the Continental US JISAO/SMA Climate Impacts.

A New Inter-Comparison of Three Global Monthly SSM/I Precipitation Datasets Matt Sapiano, Phil Arkin and Tom Smith Earth Systems Science Interdisciplinary.

1 National HIC/RH/HQ Meeting ● January 27, 2006 version: FOCUSFOCUS FOCUSFOCUS FOCUS FOCUSFOCUS FOCUSFOCUS FOCUSFOCUS FOCUSFOCUS FOCUSFOCUS FOCUSFOCUS.

Potential for medium range global flood prediction Nathalie Voisin 1, Andrew W. Wood 1, Dennis P. Lettenmaier 1 1 Department of Civil and Environmental.

Panut Manoonvoravong Bureau of research development and hydrology Department of water resources.

1 The WMO Technical Conference on Meteorological and Environmental Instruments and Methods of Observation November 2008, St. Petersburg, Russia INTERCOMPARISON.

The changing contribution of snow to the hydrology of the Fraser River Basin Do-Hyuk “DK” Kang 1, Xiaogang Shi 2, Huilin Gao 3, and Stephen J. Déry 1 1.

A 85-year Retrospective Hydrologic Analysis for the Western US Nathalie Voisin, Hyo-Seok Park, Alan F. Hamlet, Andrew W. Wood, Ned Guttman # and Dennis.

Assessing the Influence of Decadal Climate Variability and Climate Change on Snowpacks in the Pacific Northwest JISAO/SMA Climate Impacts Group and the.

SNOW SEASON FRACTIONAL FLOW 4 Trends in Eurasian Arctic runoff timing and their relationship to snow cover changes Amanda Tan 1, Jennifer C. Adam 2, Dennis.

Intercomparison of US Land Surface Hydrologic Cycles from Multi-analyses & Models NOAA 30th Annual Climate Diagnostic & Prediction Workshop, 27 October,

Validation of Satellite-derived Clear-sky Atmospheric Temperature Inversions in the Arctic Yinghui Liu 1, Jeffrey R. Key 2, Axel Schweiger 3, Jennifer.

Surface Net SW Radiation Latitude Clouds Albedo Source Reanalysis for

WMO CIMO Survey National Summaries of Methods and Instruments for Solid Precipitation Measurement - Preliminary results - R Nitu Meteorological Service.

EVALUATION OF A GLOBAL PREDICTION SYSTEM: THE MISSISSIPPI RIVER BASIN AS A TEST CASE Nathalie Voisin, Andy W. Wood and Dennis P. Lettenmaier Civil and.

Hydrological Simulations for the pan- Arctic Drainage System Fengge Su 1, Jennifer C. Adam 1, Laura C. Bowling 2, and Dennis P. Lettenmaier 1 1 Department.

1 Yun Fan, Huug van den Dool, Dag Lohmann, Ken Mitchell CPC/EMC/NCEP/NWS/NOAA Kunming, May, 2004.

Where P c (mm) is corrected precipitation, P g is gauge-measured precipitation, ΔP w and ΔP e are wetting loss and evaporation loss, respectively, ΔP t.

Adjustment of Global Gridded Precipitation for Systematic Bias Jennifer Adam Department of Civil and Environmental Engineering University of Washington.

Where P c (mm) is corrected precipitation, P g is gauge-measured precipitation, ΔP w and ΔP e are wetting loss and evaporation loss, respectively, ΔP t.

Nathalie Voisin1 , Andrew W. Wood1 , Dennis P. Lettenmaier1 and Eric F

Bias Correction of Global Gridded Precipitation for

American Geophysical Union San Francisco, December 5th - 9th 2011

Use of Extended Daily Hydroclimatalogical Records to Assess Hydrologic Variability in the Pacific Northwest Department of Civil and Environmental Engineering.

Correction of Global Precipitation Products for Orographic Effects

Limitations of Rain Gauges

Model-Based Estimation of River Flows

Streamflow Simulations of the Terrestrial Arctic Regime

Recent Climate Change Modeling Results

Multimodel Ensemble Reconstruction of Drought over the Continental U.S

On the accuracy of precipitation measurements in the Arctic

Hydrologic response of Pacific Northwest Rivers to climate change

University of Washington hydrological modeling in La Plata basin

Hydrologic issues in the measurement of snowfall

Model-Based Estimation of River Flows

A Multimodel Drought Nowcast and Forecast Approach for the Continental U.S. Dennis P. Lettenmaier Department of Civil and Environmental Engineering University.

University of Washington hydrological modeling in La Plata basin

Instrumental Surface Temperature Record

Multimodel Ensemble Reconstruction of Drought over the Continental U.S

Precip, Tmax, Tmin scaled to match CRU monthly data.

Presentation transcript:

Adjustment of Global Gridded Precipitation for Systematic Bias Jennifer Adam Department of Civil and Environmental Engineering University of Washington

Motivation Systematic bias results in a net underestimation of precipitation Systematic bias results in a net underestimation of precipitation Most global precipitation products are not adjusted for systematic bias Most global precipitation products are not adjusted for systematic bias Model runs forced with unadjusted precipitation estimates will not accurately perform a water balance Model runs forced with unadjusted precipitation estimates will not accurately perform a water balance

Wind-Induced Undercatch Snow: 10 to >50% Rain: 2 to 10% Wetting Losses 2 to 10% Evaporation Losses 0 to 4% Treatment of Trace Precipitation as Zero Significant in Cold Arid Regions Splash-out and splash-in 1 to 2% Blowing and Drifting Snow ?? Sevruk, 1982

Wind-Induced Undercatch Influencing Factors: Influencing Factors: –Wind speed –Temperature –Gauge type –Gauge height –Windshield –Exposure Nespor and Sevruk, 1999

Precipitation Gauges of the World ~50 types of National Standard gauges ~50 types of National Standard gauges Sevruk et al., 1989 Sevruk et al., 1989

1998 World Meteorological Organization (WMO) Solid Precipitation Measurement Intercomparison (Goodison et al. 1998) Goals: Goals: –Introduce reference method for gauge calibration –Derive standard method to adjust for wind-induced solid precipitation undercatch CATCH RATIO (CR) = Measured Precipitation True Precipitation True Precipitation

WMO Intercomparison Results

Objective To improve gridded precipitation data used to force large-scale hydrology models To improve gridded precipitation data used to force large-scale hydrology models

Methodology Overview Create mean monthly “catch ratios” gridded ½˚ by ½˚ globally Create mean monthly “catch ratios” gridded ½˚ by ½˚ globally Apply to existing gridded precipitation products (time-series or climatologies) during the period of 1979 through 1998 Apply to existing gridded precipitation products (time-series or climatologies) during the period of 1979 through 1998

Step 1: Selection of Correction Domain Wind-Induced Solid Precipitation Undercatch: Wind-Induced Solid Precipitation Undercatch: –Countries that experience >½ of precipitation as snow during the coldest month of the year. –30 countries in the Northern Hemisphere were selected Wind-Induced Liquid Precipitation Undercatch: Worldwide Wind-Induced Liquid Precipitation Undercatch: Worldwide Wetting Losses: Worldwide Wetting Losses: Worldwide

NOAA CPC Summary of day Stations (NCAR) NOAA CPC Summary of day Stations (NCAR) 1994 through 1998 daily data 1994 through 1998 daily data Coincident P, T max, T min, Wind Speed measurements Coincident P, T max, T min, Wind Speed measurements 7,878 stations were used (4,647 for snow analysis) 7,878 stations were used (4,647 for snow analysis) Step 2: Choose Meteorological Stations

+ Step 3: Wind-Induced Solid Precipitation Undercatch Apply on a daily basis Apply on a daily basis Assume gauge type and height per country Assume gauge type and height per country

+ Step 4: Wind-Induced Liquid Precipitation Undercatch (Legates, 1987) e.g. κ r = μ 2 w hp 2 e.g. κ r = μ 2 w hp 2 Apply on a monthly basis Apply on a monthly basis Step 5: Wetting Losses (Legates, 1987) Assume one measurement per day at each station Assume one measurement per day at each station 0.02 < ΔP wr < 0.30 mm/day 0.02 < ΔP wr < 0.30 mm/day ΔP ws = ½ ΔP wr ΔP ws = ½ ΔP wr

+ Liquid Solid Step 6: Apply Bias Adjustment Model

Step 7: Determine Mean Monthly Catch Ratios for each station Step 8: Interpolate Catch Ratios to ½ ° x ½ ° globally to ½ ° x ½ ° globally Step 9: Apply to an existing Gridded Precipitation Product Mean Monthly Observed Mean Monthly Adjusted

Canada Unique Precipitation Gauge Network Unique Precipitation Gauge Network –Liquid Precipitation: AES Type B –Solid Precipitation: ~125 Nipher Gauges ~2500 Snow Ruler Stations Previous Bias Adjustment Efforts over Canada Previous Bias Adjustment Efforts over Canada –Groisman (1998) –Mekis and Hogg (1999)

6,692 stations 6,692 stations Monthly analysis Monthly analysis Assumed CR = 90% Assumed CR = 90% 495 stations 495 stations Daily analysis Daily analysis Utilized WMO Results Utilized WMO Results

Groisman ÷ Mekis and Hogg (1979 – 1990) Ratios applied to Groisman station data Ratios applied to Groisman station data Mean Monthly Catch Ratios calculated Mean Monthly Catch Ratios calculated

Results

Gridded Catch Ratios Catch Ratio (%)

Adjusted Gridded Precipitation Catch Ratios Applied to Willmott and Matsuura (2001) Monthly Time-Series from 1979 through 1998 Catch Ratios Applied to Willmott and Matsuura (2001) Monthly Time-Series from 1979 through 1998 Precipitation (mm/month)

Adjustment Effects Global Mean Annual Increase of 11.2% Global Mean Annual Increase of 11.2% All Adjustments Wind-Induced Snow Undercatch Wetting LossesWind-Induced Rain Undercatch

Global Dataset Comparisons

Summary Adjusts existing gridded precipitation products for wind-induced undercatch and wetting losses on a mean monthly basis Adjusts existing gridded precipitation products for wind-induced undercatch and wetting losses on a mean monthly basis Effort focused on snow-dominated regions and solid precipitation undercatch Effort focused on snow-dominated regions and solid precipitation undercatch Utilizes the recent WMO Solid Precipitation Measurement Intercomparison results Utilizes the recent WMO Solid Precipitation Measurement Intercomparison results

Acknowledgements: Dennis Lettenmaier, Steve Burges, Bart Nijssen and the Land Surface Hydrology Research Group Supported by NASA grant NAG to the University of Washington.

Questions?

Limitations in Methodology

Wind-Induced Undercatch Gauge Representation Gauge Representation –Gauge type or shield uniform over country –Gauge height uniform, wind sensor height at 10 m Regression Equation Application Regression Equation Application –N and r 2 –Equation developed for what gauge?

Scoring System – Solid Precipitation

Data Set Comparisons

Comparison Against Yang et al. Greenland: Yang 2.5% lower (wind sensor height, rain undercatch eqn.) Greenland: Yang 2.5% lower (wind sensor height, rain undercatch eqn.) Siberia: Yang 1.6% lower (rain undercatch eqn.) Siberia: Yang 1.6% lower (rain undercatch eqn.) Alaska: Yang 3.5% lower (shielding,gauge height, wind sensor height, rain undercatch eqn.) Alaska: Yang 3.5% lower (shielding,gauge height, wind sensor height, rain undercatch eqn.)

Gridded Global Dataset Comparisons Adjusted Willmott 2001Legates1987 Original Willmott 2001 CRU GPCC 1994 Series Climatol Series Series Climatol Bias- Adjusted NoAdjustmentAttemptedNoAdjustmentAttemptedNoAdjustmentAttempted

Legates (1987) Global Precipitation Product ½° by ½° monthly precipitation climatology (global land areas) ½° by ½° monthly precipitation climatology (global land areas) Accounts for: Accounts for: –Wind-Induced Undercatch (Liquid and Solid) –Wetting Losses –Evaporation Losses Adjustments determined from mean monthly meteorological data Adjustments determined from mean monthly meteorological data

Mean Annual Precipitation Vs. Latitude

Determined Catch Ratio (CR) Regression Equations for the most common National Standard Precipitation Gauges Determined Catch Ratio (CR) Regression Equations for the most common National Standard Precipitation Gauges –Hellmann, US NWS 8”, Tretyakov, Nipher, others CATCH RATIO (CR) = Measured Precipitation True Precipitation True Precipitation Accounts for Wind-Induced Undercatch of Soliid Precipitation Accounts for Wind-Induced Undercatch of Soliid Precipitation WMO Intercomparison Results

Double-Fenced International Reference (DFIR) Encloses the Shielded Tretyakov Gauge Encloses the Shielded Tretyakov Gauge UCAR

Wetting Losses Influencing Factors: Influencing Factors: –Gauge type –Climate –Measurement Methodology

Evaporation Losses Influencing Factors: Influencing Factors: –Gauge type –Climate –Measurement Methodology

Wind-Induced Undercatch Wetting Losses Evaporation Losses Adjusted Precipitation Gauge-Measured Precipitation Sevruk, 1982

+ Liquid Solid Legates, 1987

+ Evaporation Losses Ignored Evaporation Losses Ignored

+ 1 CR s Use “Catch Ratio” for Solid Precipitation Use “Catch Ratio” for Solid Precipitation

Overview of Project Create mean monthly “catch ratios” gridded ½˚ by ½˚ globally Create mean monthly “catch ratios” gridded ½˚ by ½˚ globally Apply to existing gridded precipitation products (time-series or climatologies) during the period of 1979 through 1998 Apply to existing gridded precipitation products (time-series or climatologies) during the period of 1979 through 1998