DISAT-Contribution R. Ferrise, M. Moriondo and M. Bindi 1. What are the main objectives of our study? –Select/Test impact models to simulate different.

Slides:

Advertisements

Similar presentations

RT6 ENSEMBLES Kickoff Hamburg September 2004 ENSEMBLES Kickoff Meeting Hamburg - September 2004 RT6 Assessments of impacts of climate change Andy Morse,

Advertisements

On the importance of meteorological downscaling for short, medium and long-range hydrological ensemble prediction over France G. Thirel (1), F. Regimbeau.

Operational information FAO RFE for Sudan FAO & Sudan Meteorology Authority Mauro Evangelisti &Stefano Alessandrini (FAO Consultant)

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,

Climate Prediction Applications Science Workshop

EXIOPOL Presentation March Presentation of the IP Agenda Introducing EXIOPOL –IP project –Objectives –Implementation plan –Structure.

Learner-Centered Education Course Redesign Initiative Builds upon work of prior LCE grants Will award grants of $40,000 - $50,000, with the option.

Economic Impacts of Climate Change

Implementing CGMS in Morocco and the Huaibei/Juanghuai plains Allard de Wit & Raymond van der Wijngaart.

(Multi-model crop yield estimates)

ENSEMBLES Work Package 6.2 Meeting, Helsinki, Finland, April 2007 ENSEMBLES in Helsinki WELCOME / TERVETULOA!

1 ENSEMBLES 3. GA 2006, Lund – WP 6.2 Meeting 20th Nov RT6, WP 6.2 Meeting Estimates of Windstorm induced Loss in Europe ENSEMBLES GA 2006 – 20th Nov –

DISAT contribution: Development of a methodology for probabilistic assessments of climate change impacts on typical Mediterranean agric. crops (e.g. durum.

Assessment of fire risk in boreal forests under the present-day and future climate Andrea Vajda, Ari Venäläinen and Kirsti Jylhä Finnish Meteorological.

Dr. Christos Giannakopoulos Dr. Philippe LeSager Dr. Effie Kostopoulou Dr. Basil Psiloglou NATIONAL OBSERVATORY OF ATHENS (NOA) Work progress in WP6.2.

Relating changes in extremes to impacts over the Mediterranean: developments since the AGM and application to D6.8 Tom Holt Climatic Research Unit, University.

ENSEMBLES GA Prague Center for Environmental Systems Research University of Kassel Joseph Alcamo & Martina Weiß

Progress since Helsinki Tom Holt Climatic Research Unit, University of East Anglia, Norwich, UK ENSEMBLES WP6.2, Prague, November, 2007.

U N I V E R S I T Y O F A A R H U S Faculty of Agricultural Sciences Climate change impact on winter wheat yield and nitrogen leaching Preliminary analysis.

UEA contribution to ENSEMBLES WP6.2 – where we are and where we think we are going! Tom Holt Climatic Research Unit, University of East Anglia, Norwich,

Ministry of Food, Agriculture and Fisheries Danish Institute of Agricultural Sciences ENSEMBLES Tove Heidmann & Jørgen E. Olesen, DIAS.

Evaluating the impacts of climate change on hydrology and water resources Phil Graham Fredrik Wetterhall Swedish Meteorological and Hydrological Institute.

Recent progress since HelsinkiRecent progress since Helsinki Plans for the next reporting phasePlans for the next reporting phase Expected contributions.

Impacts of climate on tropical crop production Tom Osborne a Andy Challinor a,b, Tim Wheeler b, Julia Slingo a a Department of Meteorology b Department.

ENSEMBLES General Assembly, Prague, Czech Republic, November 2007 Potential WP Participants (known absentees underlined): DJF, DISAT, FMI, FUB, LUND,

The new German project KLIWEX-MED: Changes in weather and climate extremes in the Mediterranean basin Andreas Paxian, University of Würzburg MedCLIVAR.

GROWING REGIONS, GROWING EUROPE Fourth Report on Economic and Social Cohesion By Prof. Danuta Hübner Brussels, 30 May 2007.

DRC 2006.Presenters Name.March 7-9.p 1 Californias enormous computing resources allow climate simulations at unprecedented resolution capturing Californias.

MULTIPLICATION EQUATIONS 1. SOLVE FOR X 3. WHAT EVER YOU DO TO ONE SIDE YOU HAVE TO DO TO THE OTHER 2. DIVIDE BY THE NUMBER IN FRONT OF THE VARIABLE.

FACTORING Think Distributive property backwards Work down, Show all steps ax + ay = a(x + y)

Around the World AdditionSubtraction MultiplicationDivision AdditionSubtraction MultiplicationDivision.

University of Nebraska Lincoln R School of Natural Resources Water in Bioenergy Agroecosystems Workshop June 12-13, 2012 Ecosystem Scale Evapotranspiration.

AgroCLIM software tool for effective calculation of agrometeorological indices ADAGIO & COST 734 Miroslav Trnka, Petr Hlavinka, Jan Balek, Josef Eitzinger,

1 Using Bayesian Network for combining classifiers Leonardo Nogueira Matos Departamento de Computação Universidade Federal de Sergipe.

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

Probabilistic Analysis of Hydrological Loads to Optimize the Design of Flood Control Systems B. Klein, M. Pahlow, Y. Hundecha, C. Gattke and A. Schumann.

Running a model's adjoint to obtain derivatives, while more efficient and accurate than other methods, such as the finite difference method, is a computationally.

Climate change impacts and water in Western Balkan Blaz Kurnik EEA + colleagues from ETC.

Jurandir ZULLO Junior Effective use of agrometeorological systems and information Expert Meeting on Weather, Climate and Farmers.

Land use effect on nutrient loading – nutrient models new assessment tools Inese Huttunen, Markus Huttunen and Bertel Vehviläinen Finnish Environment Institute.

1 McGill University Department of Civil Engineering and Applied Mechanics Montreal, Quebec, Canada.

Applying probabilistic scenarios to environmental management and resource assessment Rob Wilby Climate Change Science Manager

RT6 RT3 and RT4/RT5 Feb 2005 Meetings ENSEMBLES Meetings RT3 Copenhagen, RT4/RT5 Paris, February 2005 RT6 Assessments of impacts of climate.

Hydrological Modeling FISH 513 April 10, Overview: What is wrong with simple statistical regressions of hydrologic response on impervious area?

Climate Variability and Prediction in the Little Colorado River Basin Matt Switanek 1 1 Department of Hydrology and Water Resources University of Arizona.

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.

Assessment of Climate Change Impact on Agriculture Giacomo Trombi, Roberto Ferrise, Marco Moriondo & Marco Bindi DiSAT – University of Florence Rome –

Impact of Climate Change on Flow in the Upper Mississippi River Basin

Page 1GMES - ENSEMBLES 2008 ENSEMBLES. Page 2GMES - ENSEMBLES 2008 The ENSEMBLES Project  Began 4 years ago, will end in December 2009  Supported by.

South Eastern Latin America LA26: Impact of GC on coastal areas of the Rio de la Plata: Sea level rise and meteorological effects LA27: Building capacity.

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.

Scaling up Crop Model Simulations to Districts for Use in Integrated Assessments: Case Study of Anantapur District in India K. J. Boote, Univ. of Florida.

Approaches to Seasonal Drought Prediction Bradfield Lyon CONAGUA Workshop Nov, 2014 Mexico City, Mexico.

Model inter-comparison on climate change in relation to grassland productivity Shaoxiu Ma, Gianni Bellocchi Romain Lardy, Haythem Ben-Touhami, Katja Klumpp.

© Crown copyright Met Office Providing High-Resolution Regional Climates for Vulnerability Assessment and Adaptation Planning Joseph Intsiful, African.

1 Evaluating and Estimating the Effect of Land use Changed on Water Quality at Selorejo Reservoir, Indonesia Mohammad Sholichin Faridah Othman Shatira.

The hydrological cycle of the western United States is expected to be significantly affected by climate change (IPCC-AR4 report). Rising temperature and.

Work Package 23: Impact models for impact predictions Karina Williams, on behalf of Jemma Gornall WP23 Participants: Met Office, Predictia, WU, IC3, UNIVLEEDS,

ENSEMBLES RT4/RT5 Joint Meeting Paris, February 2005 Overview of the WP5.3 Activities Partners: ECMWF, METO/HC, MeteoSchweiz, KNMI, IfM, CNRM, UREAD/CGAM,

Understanding hydrologic changes: application of the VIC model Vimal Mishra Assistant Professor Indian Institute of Technology (IIT), Gandhinagar

ESTIMATING THE CROP YIELD POTENTIAL OF THE CZECH REPUBLIC IN PRESENT AND CHANGED CLIMATES Martin Dubrovsky (1) Mirek Trnka (2), Zdenek Zalud (2), Daniela.

Reducing the risk of volcanic ash to aviation Natalie Harvey, Helen Dacre (Reading) Helen Webster, David Thomson, Mike Cooke (Met Office) Nathan Huntley.

Syed Aftab Wajid Associate Professor, Department of Agronomy,

Dr. Monia Santini University of Tuscia and CMCC CMCC Annual Meeting

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

The application of Models-3 in national policy Samantha Baker Air and Environment Quality Division, Defra.

South Eastern Latin America

A Data Partitioning Scheme for Spatial Regression

Presentation transcript:

DISAT-Contribution R. Ferrise, M. Moriondo and M. Bindi 1. What are the main objectives of our study? –Select/Test impact models to simulate different Mediterranean ecosystem tasks: Forestry - damage due to forest fireForestry - damage due to forest fire Agriculture - losses due to water and heat stressesAgriculture - losses due to water and heat stresses –Apply the selected models to estimate a range of impacts using the probabilistic scenarios developed in WP1.2, WP2A.3 and WP2B3-5

–DISAT research activity matches all the three main objectives of WP6.2 for months 25-42: selecting, calibrating and testing impact modelsselecting, calibrating and testing impact models constructing impact response surfaces to evaluate the impacts of climate changeconstructing impact response surfaces to evaluate the impacts of climate change defining critical thresholds for preliminary probabilistic estimates of future climate impactsdefining critical thresholds for preliminary probabilistic estimates of future climate impacts 2. How do our objectives relate to the Work Package objectives ?

–Last 12 months 3.1Complete the testing and calibration of impact models for use in estimating future risks of climate change 3.2Develop a simple statistical model that emulates process-based crop yield models (e.g. Sirius) 3.3Create preliminary yield response surfaces altering the baseline climate 3. What have we achieved so far?

Durum Wheat model Calibration (i.e. SIRIUS-Quality):Durum Wheat model Calibration (i.e. SIRIUS-Quality): –Sites: 3 –Experimental data: 4 years ( ) from Experimental Institute for Cereals –Cultivar: Creso –Model parameters: anthesis and yields 3. What have we achieved so far? (3.1 Complete the testing and calibration of impact models) Milano Roma Foggia

1.Model Validation for the application domain: –SIRIUS was tested on 6 grid points (50 Km X 50 Km) over the Mediterranean Basin using: Daily climatic data : from MARS Project databaseDaily climatic data : from MARS Project database Soil properties: from the Eusoils databaseSoil properties: from the Eusoils database Yield Data: from EUROSTAT database.Yield Data: from EUROSTAT database. 3. What have we achieved so far? (3.2 Develop simple statistical models that emulates process- based crop yield SIRIUS-Quality model) Andalucia Provence Veneto Lazio Sicilia Peloponnisos Yield (t ha -1 ) ObservedSimulated Average SD CV Pearson 0.66

2.Develop simple statistical models that emulates process-based crop yield SIRIUS model (following the approach proposed by Olesen et al., 2006) a)For each of the six grid points SIRIUS was run for the combinations of 8 climate scenarios with 4 different soil types and 5 N-rates (160 runs per grid) b)A neural network back-propagation model was trained and tested for emulating the SIRIUS outputs: Network layers: 3Network layers: 3 Input nodes: 7 (variables: SWC, N level, Ta, Pa, T(JFM), T(AMJ))Input nodes: 7 (variables: SWC, N level, Ta, Pa, T(JFM), T(AMJ)) Hidden layer nodes: 20Hidden layer nodes: 20 Output: 1Output: 1 Testing data: 30%Testing data: 30% 3. What have we achieved so far? (3.2 Develop simple statistical models that emulates process- based crop yield SIRIUS model) NN model structure Testing results

Yield response surfaces were estimated by altering baseline climate in a grid box of Southern France:Yield response surfaces were estimated by altering baseline climate in a grid box of Southern France: –Grid box: France 43.6 N, 5.0 E –Climatic data changes: Precipitation: -20% to +20%, Temperature: -2°C to +6°C –CO 2 concentration scenarios: (353, 450, 550 and 750 ppm) –Soil Water Capacity: 115 mm –Fertilization: 100 Kg N ha What have we achieved so far? (3.3 Create preliminary yield response surfaces altering the baseline climate for both models)

Tasks Tasks –Task 6.2.8: Construction of impact response surfaces for selected impact models of crops –Task 6.2.9: Preliminary scenario impacts and risk assessment from available climate projections for selected models of crops –Task : Preliminary evaluation of the impacts of extreme events using selected impact models for crops and forest fire from available climate projections –Task : Application of preliminary results from the Ensembles Prediction System to impact models for estimating risks of extremes and risks of impacts Deliverables Deliverables –Deliverable 6.7: Preliminary report on a comparative study of response surface and multiple scenario approaches to assessing risks of impacts using selected impact models. Due Feb 2007 (Month 30) –Deliverable 6.8: Preliminary report on changes in climate extremes and their relation to agriculture and forest. Due Feb 2007 (Month 30) –Deliverable 6.13: Methodological report on the linking of preliminary probabilistic projections from the Ensemble Prediction System to impact models. Due Feb 2008 (Month 42) Milestones Milestones –Milestone 6.12: Work Package 6.2 meeting to report progress in applying probabilistic information to impact models and to agree on common approaches and reporting of results. Due April 2007 (Month 32) –Milestone 6.13: Preparation of protocol for determining probabilistic information from the Ensembles Prediction System (RT 2B) and applying it to calibrated impact models. Due Aug 2007 (Month 36) –Milestone 6.14: Completion of preliminary probabilistic assessments of climate change impacts using calibrated impact models. Due Feb 2008 (Month 42) 4.Which of the WP 6.2 outputs do we plan to contribute?

– Next 18 months (months 25-42) Complete the development simple statistical models that emulates process-based crop yield models for all the three selected crops (i.e. olive, grapevine and durum wheat)Complete the development simple statistical models that emulates process-based crop yield models for all the three selected crops (i.e. olive, grapevine and durum wheat) Create yield response surfaces for all the three crops for a pilot study areaCreate yield response surfaces for all the three crops for a pilot study area Define critical thresholds of impacts and obtain preliminary estimates of the likelihood of exceeding these thresholds using probabilistic information about future climateDefine critical thresholds of impacts and obtain preliminary estimates of the likelihood of exceeding these thresholds using probabilistic information about future climate 5. What are we planning to do in the next 18 months ?

6. What are our main questions requiring discussion in this meeting? Define and collect the climate data that will be used: –to create crop yield response surfaces –to obtain preliminary estimates of the probabilistic impact of future climate change on crop yields