Presentation is loading. Please wait.

Presentation is loading. Please wait.

Hannover, 28 November 2006 Fehlergrenzen von Extremwerten des Wetters Errors bounds in extreme weather analyses Manfred Mudelsee University of Leipzig,

Published byJeremiah Napier Modified over 11 years ago

Similar presentations

Presentation on theme: "Hannover, 28 November 2006 Fehlergrenzen von Extremwerten des Wetters Errors bounds in extreme weather analyses Manfred Mudelsee University of Leipzig,"— Presentation transcript:

1 Hannover, 28 November 2006 Fehlergrenzen von Extremwerten des Wetters Errors bounds in extreme weather analyses Manfred Mudelsee University of Leipzig, Germany Climate Risk Analysis, Halle (S), Germany

2 Whats it all about? Changing risk. PresentFuture

3 Whats it all about? Changing risk. PresentFuture PastPresent

4 Message 1 Climate science:no certainty, no proofs. Rather: hypothesis tests, parameter estimates.

5 Message 2 Parameter estimates (e.g., of flood risk) without realistic error bars are useless.

6 Basics Theoretical example: o daily runoff values o one year, n = 365 What is the maximum value in a year?

7 Basics Theoretical example: 5% > 3500 m 3 s –1 return period = 20 years

8 Objective Return period estimation using data risk estimation temporal changes expected damages

9 Structure of talk 1Return period estimation 2Statistical uncertainties 3 Systematic uncertainties Example: Elbe

10 1 Return period estimation f(x)f(x) x

11 f(x)f(x) x Johnson et al. (1995) Continuous Univariate Distributions, Vol. 2, Wiley.

12 1 Return period estimation f(x)f(x) x

13 f(x)f(x) x maximize L GEV maximize likelihood that GEV model produced data

14 1 Return period estimation: Example Elbe, Dresden, 1852–2002, summer, annual maxima (n = 151) HQ 100 = 3921 m 3 s –1

15 2 Statistical uncertainties nfinite GEV parameter estimation errors > 0 return period estimation error > 0 How large is error? 1. Theoretical derivation 2. Simulation Johnson et al. (1995)

16 2 Statistical uncertainties: Simulation Jackknife simulation: Step 1:Remove randomly one point Step 2:Fit GEV, estimate return period Step 3:Go to Step 1 until 400 simulated return periods exist Step 4:Take STD over simulations

17 2 Statistical uncertainties: Example Elbe, Dresden, 1852–2002, summer, annual maxima (n = 151) Jackknife simulations of HQ 100 : 38863962389539033960 39023920391139573961 39533959388639613959 39363892383839573871 HQ 100 = 3921 m 3 s –1 Mean = 3923 m 3 s –1 STD = 38 m 3 s –1

18 3 Systematic uncertainties 3.1 Model suitability fitted GEV empirical (kernel density)

19 3 Systematic uncertainties 3.2Data errors: WQ relation Mudelsee et al. (2006) Hydrol. Sci. J. 51:818–833.Werra

20 3 Systematic uncertainties 3.2Data errors: Simulation Step 1: Q sim (i) = Q(i) + δQ WQ (i) Step 2: CombineQ sim (i) with jackknife

21 3 Systematic uncertainties PresentFuture 3.3Instationarity

22 3 Systematic uncertainties Mudelsee et al. (2003) Nature 425:166–169. 3.3Instationarity

23 3 Systematic uncertainties 3.3Instationarity = the real challenge! Time-dependent GEV parameters Work in progress...

24 Message 1 Climate science:no certainty, no proofs. Rather: hypothesis tests, parameter estimates.

25 Message 2 Parameter estimates (e.g., of flood risk) without realistic error bars are useless.

26 Message 2 Parameter estimates (e.g., of flood risk) without realistic error bars are useless. Case 1Q 100 = 3921 m 3 s –1 ± ??? Case 2Q 100 = 3921 m 3 s –1 ± 38 m 3 s –1 Case 3Q 100 = 3921 m 3 s –1 ± 300 m 3 s –1

27 THANKS!

28 Example 2: Extremes, X out (T) Elbe, winter, class 2–3 h CV = 35 yr

29 Bootstrap resample (with replacement, same size) Elbe, winter, class 2–3 h CV = 35 yr Example 2: Extremes, X out (T)

30 Bootstrap resample (with replacement, same size) Elbe, winter, class 2–3 h CV = 35 yr Example 2: Extremes, X out (T)

31 Bootstrap resample (with replacement, same size) 2nd Bootstrap resample Elbe, winter, class 2–3 h CV = 35 yr Example 2: Extremes, X out (T)

32 Bootstrap resample (with replacement, same size) 2nd Bootstrap resample 2000 Bootstrap resamples Elbe, winter, class 2–3 h CV = 35 yr Example 2: Extremes, X out (T)

33 Elbe, winter, class 2–3 h CV = 35 yr Bootstrap resample (with replacement, same size) 2nd Bootstrap resample 2000 Bootstrap resamples Example 2: Extremes, X out (T)

34 Elbe, winter, class 2–3 h CV = 35 yr Example 2: Extremes, X out (T) 90% bootstrap confidence band

35 Elbe, winter, class 2–3 h CV = 35 yr Example 2: Extremes, X out (T) 90% bootstrap confidence band Cowling et al. (1996) J. Am. Statist. Assoc. 91:1516. Mudelsee et al. (2004) J. Geophys. Res. 109:D23101.

36 Example 2: Extremes, X out (T) Mudelsee et al. (2003) Nature 425:166.

37 References http://www.uni-leipzig.de/~meteo/MUDELSEE/ http://www.climate-risk-analysis.com

Download ppt "Hannover, 28 November 2006 Fehlergrenzen von Extremwerten des Wetters Errors bounds in extreme weather analyses Manfred Mudelsee University of Leipzig,"

Similar presentations

Manfred Mudelsee Department of Earth Sciences Boston University, USA

Manfred Mudelsee Department of Earth Sciences Boston University, USA
Menéndez, Re & Kind Flood risk maps & salinity front FACULTAD DE INGENIERÍA UNIVERSIDAD DE BUENOS AIRES REGIONAL AIACC WORKSHOP Buenos Aires, Argentina.

Menéndez, Re & Kind Flood risk maps & salinity front FACULTAD DE INGENIERÍA UNIVERSIDAD DE BUENOS AIRES REGIONAL AIACC WORKSHOP Buenos Aires, Argentina.
The role of increasing temperature variability in European summer heat waves Christoph Schär, Pier Luigi Vidale, Daniel Lüthi, Christoph Frei, Christian.

The role of increasing temperature variability in European summer heat waves Christoph Schär, Pier Luigi Vidale, Daniel Lüthi, Christoph Frei, Christian.
Alexander Statnikov1, Douglas Hardin1,2, Constantin Aliferis1,3

Alexander Statnikov1, Douglas Hardin1,2, Constantin Aliferis1,3
COMPARATIVE SURVIVAL STUDY (CSS) of PIT-tagged Spring/Summer Chinook and PIT-tagged Summer Steelhead 199602000 CBFWA Implementation Review Mainstem/Systemwide.

COMPARATIVE SURVIVAL STUDY (CSS) of PIT-tagged Spring/Summer Chinook and PIT-tagged Summer Steelhead CBFWA Implementation Review Mainstem/Systemwide.
TABLE OF CONTENTS CHAPTER 5.0: Workforce

TABLE OF CONTENTS CHAPTER 5.0: Workforce
TABLE OF CONTENTS CHAPTER 5.0: Workforce Chart 5.1: Total Number of Active Physicians per 1,000 Persons, 1980 – 2009 Chart 5.2: Total Number of Active.

TABLE OF CONTENTS CHAPTER 5.0: Workforce Chart 5.1: Total Number of Active Physicians per 1,000 Persons, 1980 – 2009 Chart 5.2: Total Number of Active.
TABLE OF CONTENTS CHAPTER 5.0: Workforce Chart 5.1: Total Number of Active Physicians per 1,000 Persons, 1980 – 2008 Chart 5.2: Total Number of Active.

TABLE OF CONTENTS CHAPTER 5.0: Workforce Chart 5.1: Total Number of Active Physicians per 1,000 Persons, 1980 – 2008 Chart 5.2: Total Number of Active.
Divide-and-Conquer and Statistical Inference for Big Data

Divide-and-Conquer and Statistical Inference for Big Data
C O M P U T A T I O N A L R E S E A R C H D I V I S I O N Application of Generalized Extreme Value theory to coupled general circulation models Michael.

C O M P U T A T I O N A L R E S E A R C H D I V I S I O N Application of Generalized Extreme Value theory to coupled general circulation models Michael.
UNDERSTANDING, DETECTING AND COMPARING EXTREME PRECIPITATION CHANGES OVER MEDITERRANEAN USING CLIMATE MODELS Dr. Christina Anagnostopoulou Department of.

UNDERSTANDING, DETECTING AND COMPARING EXTREME PRECIPITATION CHANGES OVER MEDITERRANEAN USING CLIMATE MODELS Dr. Christina Anagnostopoulou Department of.
Introduction to modelling extremes

Introduction to modelling extremes
The methodology used for the 2001 SARs Special Uniques Analysis Mark Elliot Anna Manning Confidentiality And Privacy Group (www.capri.man.ac.uk) University.

The methodology used for the 2001 SARs Special Uniques Analysis Mark Elliot Anna Manning Confidentiality And Privacy Group ( University.
Modeling of Data. Basic Bayes theorem Bayes theorem relates the conditional probabilities of two events A, and B: A might be a hypothesis and B might.

Modeling of Data. Basic Bayes theorem Bayes theorem relates the conditional probabilities of two events A, and B: A might be a hypothesis and B might.
Review bootstrap and permutation

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

Probabilistic Analysis of Hydrological Loads to Optimize the Design of Flood Control Systems B. Klein, M. Pahlow, Y. Hundecha, C. Gattke and A. Schumann.
1 McGill University Department of Civil Engineering and Applied Mechanics Montreal, Quebec, Canada.

1 McGill University Department of Civil Engineering and Applied Mechanics Montreal, Quebec, Canada.
Hypothesis testing and confidence intervals by resampling by J. Kárász.

Hypothesis testing and confidence intervals by resampling by J. Kárász.
4 th International Symposium on Flood Defence Generation of Severe Flood Scenarios by Stochastic Rainfall in Combination with a Rainfall Runoff Model U.

4 th International Symposium on Flood Defence Generation of Severe Flood Scenarios by Stochastic Rainfall in Combination with a Rainfall Runoff Model U.
Lwando Kondlo Supervisor: Prof. Chris Koen University of the Western Cape 12/3/2008 SKA SA Postgraduate Bursary Conference Estimation of the parameters.

Lwando Kondlo Supervisor: Prof. Chris Koen University of the Western Cape 12/3/2008 SKA SA Postgraduate Bursary Conference Estimation of the parameters.

Similar presentations

Ads by Google