Measuring Market Risk

Kevin Dowd is Professor of Financial Risk Management at Nottingham University. Kevin is an Adjunct Scholar at the Cato Institute in Washington, D.C., and a Fellow of the Pensions Institute at Birkbeck College.

Preface to the Second Edition xiii

Acknowledgements xix

1 The Rise of Value at Risk 1

1.1 The emergence of financial risk management 2

1.2 Market risk measurement 4

1.3 Risk measurement before VaR 5

1.3.1 Gap analysis 5

1.3.2 Duration analysis 5

1.3.3 Scenario analysis 6

1.3.4 Portfolio theory 7

1.3.5 Derivatives risk measures 8

1.4 Value at risk 9

1.4.1 The origin and development of VaR 9

1.4.2 Attractions of VaR 11

1.4.3 Criticisms of VaR 13

Appendix: Types of Market Risk 15

2 Measures of Financial Risk 19

2.1 The mean–variance framework for measuring financial risk 20

2.2 Value at risk 27

2.2.1 Basics of VaR 27

2.2.2 Determination of the VaR parameters 29

2.2.3 Limitations of VaR as a risk measure 31

2.3 Coherent risk measures 32

2.3.1 The coherence axioms and their implications 32

2.3.2 The expected shortfall 35

2.3.3 Spectral risk measures 37

2.3.4 Scenarios as coherent risk measures 42

2.4 Conclusions 44

Appendix 1: Probability Functions 45

Appendix 2: Regulatory Uses of VaR 52

3 Estimating Market Risk Measures: An Introduction and Overview 53

3.1 Data 53

3.1.1 Profit/loss data 53

3.1.2 Loss/profit data 54

3.1.3 Arithmetic return data 54

3.1.4 Geometric return data 54

3.2 Estimating historical simulation VaR 56

3.3 Estimating parametric VaR 57

3.3.1 Estimating VaR with normally distributed profits/losses 57

3.3.2 Estimating VaR with normally distributed arithmetic returns 59

3.3.3 Estimating lognormal VaR 61

3.4 Estimating coherent risk measures 64

3.4.1 Estimating expected shortfall 64

3.4.2 Estimating coherent risk measures 64

3.5 Estimating the standard errors of risk measure estimators 69

3.5.1 Standard errors of quantile estimators 69

3.5.2 Standard errors in estimators of coherent risk measures 72

3.6 The core issues: an overview 73

Appendix 1: Preliminary Data Analysis 75

Appendix 2: Numerical Integration Methods 80

4 Non-parametric Approaches 83

4.1 Compiling historical simulation data 84

4.2 Estimation of historical simulation VaR and ES 84

4.2.1 Basic historical simulation 84

4.2.2 Bootstrapped historical simulation 85

4.2.3 Historical simulation using non-parametric density estimation 86

4.2.4 Estimating curves and surfaces for VAR and ES 88

4.3 Estimating confidence intervals for historical simulation VaR and ES 89

4.3.1 An order-statistics approach to the estimation of confidence intervals for HS VaR and ES 89

4.3.2 A bootstrap approach to the estimation of confidence intervals for HS VaR and ES 90

4.4 Weighted historical simulation 92

4.4.1 Age-weighted historical simulation 93

4.4.2 Volatility-weighted historical simulation 94

4.4.3 Correlation-weighted historical simulation 95

4.4.4 Filtered historical simulation 96

4.5 Advantages and disadvantages of non-parametric methods 99

4.5.1 Advantages 99

4.5.2 Disadvantages 100

4.6 Conclusions 101

Appendix 1: Estimating Risk Measures with Order Statistics 102

Appendix 2: The Bootstrap 105

Appendix 3: Non-parametric Density Estimation 111

Appendix 4: Principal Components Analysis and Factor Analysis 118

5 Forecasting Volatilities, Covariances and Correlations 127

5.1 Forecasting volatilities 127

5.1.1 Defining volatility 127

5.1.2 Historical volatility forecasts 128

5.1.3 Exponentially weighted moving average volatility 129

5.1.4 GARCH models 131

5.1.5 Implied volatilities 136

5.2 Forecasting covariances and correlations 137

5.2.1 Defining covariances and correlations 137

5.2.2 Historical covariances and correlations 138

5.2.3 Exponentially weighted moving average covariances 140

5.2.4 GARCH covariances 140

5.2.5 Implied covariances and correlations 141

5.2.6 Some pitfalls with correlation estimation 141

5.3 Forecasting covariance matrices 142

5.3.1 Positive definiteness and positive semi-definiteness 142

5.3.2 Historical variance–covariance estimation 142

5.3.3 Multivariate EWMA 142

5.3.4 Multivariate GARCH 142

5.3.5 Computational problems with covariance and correlation matrices 143

Appendix: Modelling Dependence: Correlations and Copulas 145

6 Parametric Approaches (I) 151

6.1 Conditional vs unconditional distributions 152

6.2 Normal VaR and ES 154

6.3 The t-distribution 159

6.4 The lognormal distribution 161

6.5 Miscellaneous parametric approaches 165

6.5.1 Lévy approaches 165

6.5.2 Elliptical and hyperbolic approaches 167

6.5.3 Normal mixture approaches 167

6.5.4 Jump diffusion 168

6.5.5 Stochastic volatility approaches 169

6.5.6 The Cornish–Fisher approximation 171

6.6 The multivariate normal variance–covariance approach 173

6.7 Non-normal variance–covariance approaches 176

6.7.1 Multivariate t-distributions 176

6.7.2 Multivariate elliptical distributions 177

6.7.3 The Hull–White transformation-into-normality approach 177

6.8 Handling multivariate return distributions with copulas 178

6.8.1 Motivation 178

6.8.2 Estimating VaR with copulas 179

6.9 Conclusions 182

Appendix: Forecasting Longer-term Risk Measures 184

7 Parametric Approaches (II): Extreme Value 189

7.1 Generalised extreme-value theory 190

7.1.1 Theory 190

7.1.2 A short-cut EV method 194

7.1.3 Estimation of EV parameters 195

7.2 The peaks-over-threshold approach: the generalised Pareto distribution 201

7.2.1 Theory 201

7.2.2 Estimation 203

7.2.3 GEV vs POT 204

7.3 Refinements to EV approaches 204

7.3.1 Conditional EV 204

7.3.2 Dealing with dependent (or non-iid) data 205

7.3.3 Multivariate EVT 206

7.4 Conclusions 206

8 Monte Carlo Simulation Methods 209

8.1 Uses of Monte carlo simulation 210

8.2 Monte Carlo simulation with a single risk factor 213

8.3 Monte Carlo simulation with multiple risk factors 215

8.4 Variance-reduction methods 217

8.4.1 Antithetic variables 218

8.4.2 Control variates 218

8.4.3 Importance sampling 219

8.4.4 Stratified sampling 220

8.4.5 Moment matching 223

8.5 Advantages and disadvantages of Monte Carlo simulation 225

8.5.1 Advantages 225

8.5.2 Disadvantages 225

8.6 Conclusions 225

9 Applications of Stochastic Risk Measurement Methods 227

9.1 Selecting stochastic processes 227

9.2 Dealing with multivariate stochastic processes 230

9.2.1 Principal components simulation 230

9.2.2 Scenario simulation 232

9.3 Dynamic risks 234

9.4 Fixed-income risks 236

9.4.1 Distinctive features of fixed-income problems 237

9.4.2 Estimating fixed-income risk measures 237

9.5 Credit-related risks 238

9.6 Insurance risks 240

9.6.1 General insurance risks 241

9.6.2 Life insurance risks 242

9.7 Measuring pensions risks 244

9.7.1 Estimating risks of defined-benefit pension plans 245

9.7.2 Estimating risks of defined-contribution pension plans 246

9.8 Conclusions 248

10 Estimating Options Risk Measures 249

10.1 Analytical and algorithmic solutions for options VaR 249

10.2 Simulation approaches 253

10.3 Delta–gamma and related approaches 256

10.3.1 Delta–normal approaches 257

10.3.2 Delta–gamma approaches 258

10.4 Conclusions 264

11 Incremental and Component Risks 265

11.1 Incremental VaR 265

11.1.1 Interpreting Incremental VaR 265

11.1.2 Estimating IVaR by brute force: the ‘before and after’ approach 266

11.1.3 Estimating IVaR using analytical solutions 267

11.2 Component VaR 271

11.2.1 Properties of component VaR 271

11.2.2 Uses of component VaR 274

11.3 Decomposition of coherent risk measures 277

12 Mapping Positions to Risk Factors 279

12.1 Selecting core instruments 280

12.2 Mapping positions and VaR estimation 281

12.2.1 Basic building blocks 281

12.2.2 More complex positions 287

13 Stress Testing 291

13.1 Benefits and difficulties of stress testing 293

13.1.1 Benefits of stress testing 293

13.1.2 Difficulties with stress tests 295

13.2 Scenario analysis 297

13.2.1 Choosing scenarios 297

13.2.2 Evaluating the effects of scenarios 300

13.3 Mechanical stress testing 303

13.3.1 Factor push analysis 303

13.3.2 Maximum loss optimisation 305

13.3.3 CrashMetrics 305

13.4 Conclusions 306

14 Estimating Liquidity Risks 309

14.1 Liquidity and liquidity risks 309

14.2 Estimating liquidity-adjusted VaR 310

14.2.1 The constant spread approach 311

14.2.2 The exogenous spread approach 312

14.2.3 Endogenous-price approaches 314

14.2.4 The liquidity discount approach 315

14.3 Estimating liquidity at risk (LaR) 316

14.4 Estimating liquidity in crises 319

15 Backtesting Market Risk Models 321

15.1 Preliminary data issues 321

15.2 Backtests based on frequency tests 323

15.2.1 The basic frequency backtest 324

15.2.2 The conditional testing (Christoffersen) backtest 329

15.3 Backtests based on tests of distribution equality 331

15.3.1 Tests based on the Rosenblatt transformation 331

15.3.2 Tests using the Berkowitz transformation 333

15.3.3 Overlapping forecast periods 335

15.4 Comparing alternative models 336

15.5 Backtesting with alternative positions and data 339

15.5.1 Backtesting with alternative positions 340

15.5.2 Backtesting with alternative data 340

15.6 Assessing the precision of backtest results 340

15.7 Summary and conclusions 342

Appendix: Testing Whether Two Distributions are Different 343

16 Model Risk 351

16.1 Models and model risk 351

16.2 Sources of model risk 353

16.2.1 Incorrect model specification 353

16.2.2 Incorrect model application 354

16.2.3 Implementation risk 354

16.2.4 Other sources of model risk 355

16.3 Quantifying model risk 357

16.4 Managing model risk 359

16.4.1 Managing model risk: some guidelines for risk practitioners 359

16.4.2 Managing model risk: some guidelines for senior managers 360

16.4.3 Institutional methods to manage model risk 361

16.5 Conclusions 363

Bibliography 365

Index 379