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Loss Models. Further Topics. Edition No. 1. Wiley Series in Probability and Statistics

  • Book

  • 368 Pages
  • September 2013
  • John Wiley and Sons Ltd
  • ID: 2488438

An essential resource for constructing and analyzing advanced actuarial models Loss Models: Further Topics presents extended coverage of modeling through the use of tools related to risk theory, loss distributions, and survival models. The book uses these methods to construct and evaluate actuarial models in the fields of insurance and business. Providing an advanced study of actuarial methods, the book features extended discussions of risk modeling and risk measures, including Tail-Value-at-Risk. Loss Models: Further Topics contains additional material to accompany the Fourth Edition of Loss Models: From Data to Decisions, such as:

  • Extreme value distributions
  • Coxian and related distributions
  • Mixed Erlang distributions
  • Computational and analytical methods for aggregate claim models
  • Counting processes
  • Compound distributions with time-dependent claim amounts
  • Copula models
  • Continuous time ruin models
  • Interpolation and smoothing

The book is an essential reference for practicing actuaries and actuarial researchers who want to go beyond the material required for actuarial qualification. Loss Models: Further Topics is also an excellent resource for graduate students in the actuarial field.

Table of Contents

Preface xi

1 Introduction 1

2 Coxian and related distributions 3

2.1 Introduction 3

2.2 Combinations of exponentials 4

2.3 Coxian-2 distributions 7

3 Mixed Erlang distributions 11

3.1 Introduction 11

3.2 Members of the mixed Erlang class 12

3.3 Distributional properties 18

3.4 Mixed Erlang claim severity models 22

4 Extreme value distributions 23

4.1 Introduction 23

4.2 Distribution of the maximum 25

4.2.1 From a fixed number of losses 25

4.2.2 From a random number of losses 27

4.3 Stability of the maximum of the extreme value distribution 29

4.4 The Fisher–Tippett theorem 30

4.5 Maximum domain of attraction 32

4.6 Generalized Pareto distributions 34

4.7 Stability of excesses of the generalized Pareto 36

4.8 Limiting distributions of excesses 37

4.9 Parameter estimation 39

4.9.1 Maximum likelihood estimation from the extreme value distribution 39

4.9.2 Maximum likelihood estimation for the generalized Pareto distribution 42

4.9.3 Estimating the Pareto shape parameter 44

4.9.4 Estimating extreme probabilities 47

4.9.5 Mean excess plots 49

4.9.6 Further reading 49

4.9.7 Exercises 49

5 Analytic and related methods for aggregate claim models 51

5.1 Introduction 51

5.2 Elementary approaches 53

5.3 Discrete analogues 58

5.4 Right-tail asymptotics for aggregate losses 63

5.4.1 Exercises 71

6 Computational methods for aggregate models 73

6.1 Recursive techniques for compound distributions 73

6.2 Inversion methods 75

6.2.1 Fast Fourier transform 75

6.2.2 Direct numerical inversion 78

6.3 Calculations with approximate distributions 80

6.3.1 Arithmetic distributions 80

6.3.2 Empirical distributions 83

6.3.3 Piecewise linear cdf 84

6.3.4 Exercises 85

6.4 Comparison of methods 86

6.5 The individual risk model 87

6.5.1 Definition and notation 87

6.5.2 Direct calculation 88

6.5.3 Recursive calculation 89

7 Counting Processes 97

7.1 Nonhomogeneous birth processes 97

7.1.1 Exercises 112

7.2 Mixed Poisson processes 112

7.2.1 Exercises 116

8 Discrete Claim Count Models 119

8.1 Unification of the (a, b, 1) and mixed Poisson classes 119

8.2 A class of discrete generalized tail-based distributions 127

8.3 Higher order generalized tail-based distributions 134

8.4 Mixed Poisson properties of generalized tail-based distributions 139

8.5 Compound geometric properties of generalized tail-based distributions 146

8.5.1 Exercises 156

9 Compound distributions with time dependent claim amounts 159

9.1 Introduction 159

9.2 A model for inflation 163

9.3 A model for claim payment delays 173

10 Copula models 187

10.1 Introduction 187

10.2 Sklar’s theorem and copulas 188

10.3 Measures of dependency 189

10.3.1 Spearman’s rho 190

10.3.2 Kendall’s tau 190

10.4 Tail dependence 191

10.5 Archimedean copulas 192

10.5.1 Exercise 197

10.6 Elliptical copulas 197

10.6.1 Exercise 199

10.7 Extreme value copulas 200

10.7.1 Exercises 202

10.8 Archimax copulas 203

10.9 Estimation of parameters 203

10.9.1 Introduction 203

10.9.2 Maximum likelihood estimation 204

10.9.3 Semiparametric estimation 206

10.9.4 The role of deductibles 206

10.9.5 Goodness-of-fit testing 208

10.9.6 An example 209

10.9.7 Exercise 210

10.10 Simulation from Copula Models 211

10.10.1 Simulating from the Gaussian copula 213

10.10.2 Simulating from the t copula 213

11 Continuous-time ruin models 215

11.1 Introduction 215

11.1.1 The Poisson process 215

11.1.2 The continuous-time problem 216

11.2 The adjustment coefficient and Lundberg’s inequality 217

11.2.1 The adjustment coefficient 217

11.2.2 Lundberg’s inequality 221

11.2.3 Exercises 223

11.3 An integrodifferential equation 224

11.3.1 Exercises 228

11.4 The maximum aggregate loss 229

11.4.1 Exercises 238

11.5 Cramer’s asymptotic ruin formula and Tijms’ approximation 240

11.5.1 Exercises 243

11.6 The Brownian motion risk process 245

11.7 Brownian motion and the probability of ruin 249

12 Interpolation and smoothing 255

12.1 Introduction 255

12.2 Interpolation with splines 257

12.2.1 Exercises 263

12.3 Extrapolating with splines 264

12.3.1 Exercise 265

12.4 Smoothing with splines 265

12.4.1 Exercise 272

A An inventory of continuous distributions 273

A.1 Introduction 273

A.2 Transformed beta family 277

A.2.1 Four-parameter distribution 277

A.2.2 Three-parameter distributions 277

A.2.3 Two-parameter distributions 279

A.3 transformed gamma family 281

A.3.1 Three-parameter distributions 281

A.3.2 Two-parameter distributions 282

A.3.3 One-parameter distributions 283

A.4 Distributions for large losses 284

A.4.1 Extreme value distributions 284

A.4.2 Generalized Pareto distributions 285

A.5 Other distributions 285

A.6 Distributions with finite support 287

B An inventory of discrete distributions 289

B.1 Introduction 289

B.2 The (a, b, 0) class 290

B.3 The (a, b, 1) class 291

B.3.1 The zero-truncated subclass 291

B.3.2 The zero-modified subclass 293

B.4 The compound class 294

B.4.1 Some compound distributions 294

B.5 A hierarchy of discrete distributions 295

C Discretization of the severity distribution 297

C.1 The method of rounding 297

C.2 Mean preserving 298

C.3 Undiscretization of a discretized distribution 298

D Solutions to Exercises 301

D.1 Chapter 4 301

D.2 Chapter 5 303

D.3 Chapter 6 304

D.4 Chapter 7 305

D.5 Chapter 8 312

D.6 Chapter 10 316

D.7 Chapter 11 319

D.8 Chapter 12 333

References 339

Index 345

Authors

Stuart A. Klugman Society of Actuaries; Schaumburg, IL. Harry H. Panjer Universtiy of Waterloo, Canada. Gordon E. Willmot Universtiy of Waterloo, Canada.