Stochastic Disagregation of Monthly Rainfall Data for Crop Simulation Studies Amor VM Ines and James W Hansen International Institute for Climate Prediction.

Slides:

Advertisements

Similar presentations

D. W. Shin, S. Cocke, Y.-K. Lim, T. E. LaRow, G. A. Baigorria, and J. J. OBrien Center for Ocean-Atmospheric Prediction Studies Florida State University,

Advertisements

Dr. Adriana-Cornelia Marica & Alexandru Daniel

A Crop Simulation System for Integrating Remote Sensing and Climate Information to Reduce Model Uncertainty in Crop Yield Assessments Kiyoshi Honda 1,

Regional Impact Assessment AgMIP SSA Kickoff Workshop John Antle AgMIP Regional Econ Team Leader 1 Accra, Ghana Sept

Agricultural modelling and assessments in a changing climate

Simulating Cropping Systems in the Guinea Savanna Zone of Northern Ghana with DSSAT-CENTURY J. B. Naab 1, Jawoo Koo 2, J.W. Jones 2, and K. J. Boote 2,

Will Climate Forecasting and New Knowledge Tools help Resource-Poor Farmers move from poverty to prosperity? Farmers’ Participatory Approach to Manage.

Recent S/I Prediction Activities at IRI. IRI Climate Predictability Tool (CPT) Simon Mason.

Enhancing the Scale and Relevance of Seasonal Climate Forecasts - Advancing knowledge of scales Space scales Weather within climate Methods for information.

Translating Climate Forecasts into Agricultural Terms: Advances and Challenges James Hansen, Andrew Challinor, Amor Ines, Tim Wheeler, Vincent Moron presented.

Details for Today: DATE:3 rd February 2005 BY:Mark Cresswell FOLLOWED BY:Assignment 2 briefing Evaluation of Model Performance 69EG3137 – Impacts & Models.

Impact of climate scenarios on vulnerability and coping Impact of climate scenarios on vulnerability and coping or “How does the climate modeler fit in.

Mechanistic crop modelling and climate reanalysis Tom Osborne Crops and Climate Group Depts. of Meteorology & Agriculture University of Reading.

Crop yield predictions using seasonal climate forecasts SIMONE SIEVERT DA COSTA DSA/CPTEC/INPE Second EUROBRISA Workshop July.

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

Heiko Paeth Statistical postprocessing of simulated precipitation – perspectives for impact research IMSC 2010 Heiko Paeth.

5. CONCLUSIONS Initially constructed and applied for the New York State’s rainfall stations (Wilks, 1998), DUM was able to reproduce its good performance.

Application to the rice production in Southeast Asia Rice Production Research Program Agro-meteorology Division National Institute for Agro-Environmental.

Linking Seasonal Forecast To A Crop Yield Model SIMONE SIEVERT DA COSTA DSA/CPTEC/INPE – CNPq HOMERO BERGAMASCHI UFRGS First EUROBRISA.

INTRODUCTION Weather and climate remain among the most important variables involved in crop production in the U.S. Great Lakes region states of Michigan,

Development of a combined crop and climate forecasting system Tim Wheeler and Andrew Challinor Crops and Climate Group.

Application of seasonal climate forecasts to predict regional scale crop yields in South Africa Trevor Lumsden and Roland Schulze School of Bioresources.

Federal Department of Home Affairs FDHA Federal Office of Meteorology and Climatology MeteoSwiss Synthetic future weather time-series at the local scale.

SECC – CCSP Meeting November 7, 2008 Downscaling GCMs to local and regional levels Institute of Food and Agricultural Sciences Guillermo A. Baigorria

Multi-Model Ensembling for Seasonal-to-Interannual Prediction: From Simple to Complex Lisa Goddard and Simon Mason International Research Institute for.

Climate Forecasting Unit Second Ph’d training talk Prediction of climate extreme events at seasonal and decadal time scale Aida Pintó Biescas.

Downscaling in time. Aim is to make a probabilistic description of weather for next season –How often is it likely to rain, when is the rainy season likely.

Climate Forecasting Unit Prediction of climate extreme events at seasonal and decadal time scale Aida Pintó Biescas.

Zhang Mingwei 1, Deng Hui 2,3, Ren Jianqiang 2,3, Fan Jinlong 1, Li Guicai 1, Chen Zhongxin 2,3 1. National satellite Meteorological Center, Beijing, China.

DEMETER Taiwan, October 2003 Development of a European Multi-Model Ensemble System for Seasonal to Interannual Prediction   DEMETER Noel Keenlyside,

Weather Generator Methods

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

Volcanoes and decadal forecasts with EC-Earth Martin Ménégoz, Francisco Doblas-Reyes, Virginie Guemas, Asif Muhammad EC-Earth Meeting, Reading, May 2015.

Crop-Weather Models Observed soybean yields (GA yield trials) vs. seasonal rainfall, temperature, simulated yields.

Evaluation of climate change impact on soil and snow processes in small watersheds of European part of Russia using various scenarios of climate Lebedeva.

Young-Kwon Lim Collaborators: Climate modeling group (Drs. L. Stefanova, D.W. Shin, S. Cocke, and T. E. LaRow) at FSU/COAPS, Dr. G. Baigorria (Univ. of.

CLIMATE CHANGE AND PRECIPITATION NEEDS OF WINTER WHEAT Éva Erdélyi, Corvinus University of Budapest Levente Horváth, University of Debrecen

Model validation Simon Mason Seasonal Forecasting Using the Climate Predictability Tool Bangkok, Thailand, 12 – 16 January 2015.

Model dependence and an idea for postprocessing multi-model ensembles Craig H. Bishop Naval Research Laboratory, Monterey, CA, USA Gab Abramowitz Climate.

Young-Kwon Lim, D.W. Shin, S. Cocke, T. E. LaRow, J. J. O’Brien, and E. P. Chassignet Center for Ocean-Atmospheric Prediction Studies, Florida State University,

Dongkyun Kim and Francisco Olivera Zachry Department of Civil Engineering Texas A&M University American Society Civil Engineers Environmental and Water.

Fredrik Wetterhall, EGU2014 Slide 1 of 16 Forecasting droughts in East Africa Emmah Mwangi 1, Fredrik Wetterhall 2, Emanuel Dutra 2, Francesca Di Giuseppe.

11 Predictability of Monsoons in CFS V. Krishnamurthy Center for Ocean-Land-Atmosphere Studies Institute of Global Environment and Society Calverton, MD.

Information-based potential climate predictability Youmin Tang University of Northern British Columbia, Canada.

Crop yield predictions using seasonal climate forecasts Simone M. S. Costa and Caio A. S. Coelho Instituto Nacional de Pesquisas Espaciais – INPE, São.

D11 Summary: The need for downscaling of extremes: An evaluation of interannual variations in the NCEP reanalysis over European regions.

Interannual Variability of the Rainy Season in the Tropics of South America Brant Liebmann NOAA-CIRES Climate Diagnostics Center Boulder, Colorado, USA.

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

The Centre for Australian Weather and Climate Research A partnership between CSIRO and the Bureau of Meteorology Verification and Metrics (CAWCR)

Mike Dettinger USGS, La Jolla, CA DOWNSCALING to local climate.

Sources of Skill and Error in Long Range Columbia River Streamflow Forecasts: A Comparison of the Role of Hydrologic State Variables and Winter Climate.

El Niño-Southern Oscillation Impact on Nitrogen Leaching in North Florida Dairy Forage Systems Victor E. Cabrera*, Peter E. Hildebrand, and James W. Jones.

One-year re-forecast ensembles with CCSM3.0 using initial states for 1 January and 1 July in Model: CCSM3 is a coupled climate model with state-of-the-art.

Judith Curry James Belanger Mark Jelinek Violeta Toma Peter Webster 1

Statistical and Dynamical Downscaling of Atmospheric Model Outputs : A Hydrologic Modeler’s Perspective George Leavesley 1, Lauren Hay 1, Martyn Clark.

VERIFICATION OF A DOWNSCALING SEQUENCE APPLIED TO MEDIUM RANGE METEOROLOGICAL PREDICTIONS FOR GLOBAL FLOOD PREDICTION Nathalie Voisin, Andy W. Wood and.

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.

1. Session Goals 2 __________________________________________ FAMINE EARLY WARNING SYSTEMS NETWORK Become familiar with the available data sources for.

Long-lead streamflow forecasts: 2. An approach based on ensemble climate forecasts Andrew W. Wood, Dennis P. Lettenmaier, Alan.F. Hamlet University of.

International Workshop on Monthly-to-Seasonal Climate Prediction National Taiwan Normal Univ., October 2003 Evaluation of the APCN Multi-Model Ensemble.

Global Circulation Models

Considerations in Using Climate Change Information in Hydrologic Models and Water Resources Assessments JISAO Center for Science in the Earth System Climate.

Makarand A. Kulkarni Indian Institute of Technology, Delhi

Looking for universality...

With special thanks to Prof. V. Moron (U

Shuhua Li and Andrew W. Robertson

Predictability of Indian monsoon rainfall variability

University of Washington Center for Science in the Earth System

Stochastic Storm Rainfall Simulation

Predictors Observed rainfall up to May.

Presentation transcript:

Stochastic Disagregation of Monthly Rainfall Data for Crop Simulation Studies Amor VM Ines and James W Hansen International Institute for Climate Prediction The Earth Institute at Columbia University Palisades, NY, USA Stochastic disaggregation, and deterministic bias correction of GCM outputs for crop simulation studies

Linkage to crop simulation models Seasonal Climate Forecasts Crop simulation models (DSSAT) Crop forecasts <<<GAP>>> Daily Weather Sequence

a) Stochastic disaggregation Monthly rainfall Stochastic disaggregation Crop simulation models (DSSAT) Weather Realizations Crop forecasts GCM ensemble forecasts Stochastic weather generator >> >>

b) Bias correction of daily GCM outputs 24 GCM ensemble members Bias correction of daily outputs Crop simulation models (DSSAT) Weather Realizations Crop forecasts >> >>

To present stochastic disaggregation, and deterministic bias correction as methods for generating daily weather sequences for crop simulation models To evaluate the performance of the two methods using the results of our experiments in Southeastern US (Tifton, GA; Gainesville, FL) and Katumani, Machakos Province, Kenya. Objectives

Part I. Stochastic disaggregation of monthly rainfall amounts

Structure of a stochastic weather generator u f(u) u<=p c ? x f(x) Generate ppt.=0 p c =p 01 p c =p 11 Wet-day non-ppt. parameters: μ k,1 ; σ k,1 Dry-day non-ppt. parameters: μ k,0 ; σ k,0 Generate today’s non- ppt. variables Generate uniform random number Precipitation sub-modelNon-precipitation sub- model (after Wilks and Wilby, 1999) Generate a non- zero ppt. (Begin next day)INPUT OUTPUT

Precipitation sub-model p 01 =Pr{ppt. on day t | no ppt. on day t-1} p 11 =Pr{ppt. on day t | ppt. on day t-1} f(x)=α/β 1 exp[-x/β 1 ] + (1-α)/β 2 exp[-x/β 2 ] μ= αβ 1 + (1-α)β 2 σ 2 = αβ (1-α)β α(1-α)(β 1 -β 2 ) Max. Likelihood (MLH) Markovian process Mixed- exponential Occurrence model: Intensity model:

Long term rainfall frequency: First lag auto-correlation of occurrence series: π=p 01 /(1+p 01 -p 11 ) r 1 =p 11 -p 01

Temperature and radiation model zAzB z(t)=[A]z(t-1)+[B]ε(t) z k (t)=a k,1 z 1 (t-1)+a k,2 z 2 (t-1)+a k,3 z 3 (t-1)+ b k,1 ε 1 (t)+b k,2 ε 2 (t)+b k,3 ε 3 (t) b k,1 ε 1 (t)+b k,2 ε 2 (t)+b k,3 ε 3 (t) T k (t)= μ k,0 (t)+σ k,0 z k (t); if day t is dry μ k,1 (t)+σ k,1 z k (t); if day t is wet Trivariate 1 st order autoregressive conditional normal model NOTE: Used long-term conditional means of TMAX,TMIN,SRAD

Decomposing monthly rainfall totals R m =μ x π Dimensional analysis: where: R m - mean monthly rainfall amounts, mm d -1 μ - mean rainfall intensity, mm wd -1 π - rainfall frequency, wd d -1

Conditioning weather generator inputs μ = R m /π we condition α in the intensity model π = R m / μ we condition p 01, p 11 from the frequency and auto-correlation equations …and other higher order statistics

Conditioning weather generator outputs First step: Iterative procedure - by fixing the input parameters of the weather generator using climatological values, generate the best realization using the test criterion |1-R mSim /R m | j <= 5% Second step: Rescale the generated daily rainfall amounts at month j by (R m /R mSim ) j

Applications A.1 Diagnostic case study –Locations: Tifton, GA and Gainesville, FL –Data: A.2 Prediction case study –Location: Katumani, Kenya –Data: MOS corrected GCM outputs (ECHAM4.5) –ONDJF ( )

Crop Model: CERES-Maize in DSSATv3.5 Crop: Maize (McCurdy 84aa) Sowing dates: Apr – Tifton Mar – Gainesville Soils: Tifton loamy sand #25 – Tifton Millhopper Fine Sand – Gainesville Millhopper Fine Sand – Gainesville Soil depth: 170cm; Extr. H 2 O:189.4mm – Tifton 180cm; Extr. H 2 O:160.9mm – Gainesville 180cm; Extr. H 2 O:160.9mm – Gainesville Scenario: Rainfed Condition Simulation period: Simulation Data (Tifton, GA and Gainesville, FL)

Sensitivity of RMSE and correlation of yield Tifton, GAGainesville, FL A.1 Diagnostic Case RmRmRmRm π μ

Gainesville, FL Sensitivity of RMSE and R of rainfall amount, frequency and intensity at month of anthesis (May) RmRmRmRm μ π RmRmRmRm π μ

Gainesville, FL μ π RmRm 1000Realizations Predicted Yields

A.2 Case study: Katumani, Machakos Province, Kenya Skill of the MOS corrected GCM data OND

Simulation Data (Katumani, Machakos Province, Kenya) Crop Model: CERES-Maize Crop: Maize (KATUMANI B) Sowing dates (Nov ) Soil depth :130cm Extr. H 2 O:177.0mm Scenario: Rainfed Simulation period: Sowing strategy: conditional-forced

Sensitivity of RMSE and correlation of yield π1 (Conditioned) R m (Hindcast) π2 (Hindcast) R m +π2

R m (Hindcast) R m + π2 π1 (Conditioned) π2 (Hindcast)

Part II. Bias correction of daily GCM outputs (precipitation)

Statement of the problem RmRmRmRm Climatology, Monthly rainfall

RmRmRmRm Variance, Monthly rainfall

π μ Intensity Frequency

Proposed bias correction (a)-correcting frequency (b)-correcting intensity

Application Location: Katumani, Machakos, Kenya Climate model: ECHAM4.5 (Lat. 15S;Long. 35E) Crop Model: CERES-Maize Crop: Maize (KATUMANI B) Sowing dates (Nov ) Soil depth :130cm; Extr. H 2 O:177.0mm Scenario: Rainfed Simulation period: Sowing strategy: conditional-forced

Results RmRmRmRm μ Variance, R m μ Variance, μ

π

Sensitivity of RMSE and correlation of yield

Comparison of yield predictions using disaggregated, MOS-corrected monthly GCM predictions, and bias- corrected daily gridcell GCM simulations

Bias corrected seasonal rainfall (OND) RmRmRmRm μ π

Comparison of MOS corrected and bias corrected seasonal rainfall (OND)

Why are we successful? Is the procedure applicable in every situation? Inter-annual correlation (R) of monthly rainfall

Inter-annual variability of monthly rainfall for November

Conclusions Stochastic disaggregation: –Conditioning the outputs to match target monthly rainfall totals works better than conditioning the inputs of the weather generator: –i) it tends to minimize the variability of monthly rainfall within realizations; –ii) tends to reproduce better the historic intensity and frequency; – iii) requires fewer realizations to achieve a given level of accuracy in crop yield prediction

Deterministic bias correction of daily GCM precip: –There are useful information hidden in daily GCM outputs –Extracting them entails interpreting the data according to the GCM climatology then correcting them based on observed climatology Overall, the success of stochastic disaggregation or bias correction of GCM outputs for crop yield prediction depends greatly on the skill of the GCM THANK YOU…