JACK CLARK FRANCIS is Professor of Economics and Finance at Bernard M. Baruch College in New York City. His research focuses on investments, banking, and monetary economics, and he has had dozens of articles published in many refereed academic, business, and government journals. Dr. Francis was an assistant professor of finance at the University of Pennsylvania's Wharton School of Finance for five years and was a Federal Reserve economist for two years. He received his bachelor's and MBA from Indiana University and earned his PhD in finance from the University of Washington in Seattle.

DONGCHEOL KIM is a Professor of Finance at Korea University in Seoul. He served as president of the Korea Securities Association and editor-in-chief of the Asia-Pacific Journal of Financial Studies. Previously, he was a finance professor at Rutgers University. Kim has published articles in Financial Management, the Accounting Review, Journal of Financial and Quantitative Analysis, Journal of Economic Research, Journal of Finance, and Journal of the Futures Market.

Preface xvii

CHAPTER 1 Introduction 1

1.1 The Portfolio Management Process 1

1.2 The Security Analyst's Job 1

1.3 Portfolio Analysis 2

1.3.1 Basic Assumptions 3

1.3.2 Reconsidering the Assumptions 3

1.4 Portfolio Selection 5

1.5 The Mathematics is Segregated 6

1.6 Topics to be Discussed 6

Appendix: Various Rates of Return 7

A1.1 Calculating the Holding Period Return 7

A1.2 After-Tax Returns 8

A1.3 Discrete and Continuously Compounded Returns 8

PART ONE Probability Foundations

CHAPTER 2 Assessing Risk 13

2.1 Mathematical Expectation 13

2.2 What Is Risk? 15

2.3 Expected Return 16

2.4 Risk of a Security 17

2.5 Covariance of Returns 18

2.6 Correlation of Returns 19

2.7 Using Historical Returns 20

2.8 Data Input Requirements 22

2.9 Portfolio Weights 22

2.10 A Portfolio's Expected Return 23

2.11 Portfolio Risk 23

2.12 Summary of Notations and Formulas 27

CHAPTER 3 Risk and Diversi¿cation 29

3.1 Reconsidering Risk 29

3.1.1 Symmetric Probability Distributions 31

3.1.2 Fundamental Security Analysis 32

3.2 Utility Theory 32

3.2.1 Numerical Example 33

3.2.2 Indifference Curves 35

3.3 Risk-Return Space 36

3.4 Diversi¿cation 38

3.4.1 Diversi¿cation Illustrated 38

3.4.2 Risky A + Risky B = Riskless Portfolio 39

3.4.3 Graphical Analysis 40

3.5 Conclusions 41

PART TWO Utility Foundations

CHAPTER 4 Single-Period Utility Analysis 45

4.1 Basic Utility Axioms 46

4.2 The Utility of Wealth Function 47

4.3 Utility of Wealth and Returns 47

4.4 Expected Utility of Returns 48

4.5 Risk Attitudes 52

4.5.1 Risk Aversion 52

4.5.2 Risk-Loving Behavior 56

4.5.3 Risk-Neutral Behavior 57

4.6 Absolute Risk Aversion 59

4.7 Relative Risk Aversion 60

4.8 Measuring Risk Aversion 62

4.8.1 Assumptions 62

4.8.2 Power, Logarithmic, and Quadratic Utility 62

4.8.3 Isoelastic Utility Functions 64

4.8.4 Myopic, but Optimal 65

4.9 Portfolio Analysis 66

4.9.1 Quadratic Utility Functions 67

4.9.2 Using Quadratic Approximations to Delineate Max[E(Utility)] Portfolios 68

4.9.3 Normally Distributed Returns 69

4.10 Indifference Curves 69

4.10.1 Selecting Investments 71

4.10.2 Risk-Aversion Measures 73

4.11 Summary and Conclusions 74

Appendix: Risk Aversion and Indifference Curves 75

A4.1 Absolute Risk Aversion (ARA) 75

A4.2 Relative Risk Aversion (RRA) 76

A4.3 Expected Utility of Wealth 77

A4.4 Slopes of Indifference Curves 77

A4.5 Indifference Curves for Quadratic Utility 79

PART THREE Mean-Variance Portfolio Analysis

CHAPTER 5 Graphical Portfolio Analysis 85

5.1 Delineating Ef¿cient Portfolios 85

5.2 Portfolio Analysis Inputs 86

5.3 Two-Asset Isomean Lines 87

5.4 Two-Asset Isovariance Ellipses 90

5.5 Three-Asset Portfolio Analysis 92

5.5.1 Solving for One Variable Implicitly 93

5.5.2 Isomean Lines 96

5.5.3 Isovariance Ellipses 97

5.5.4 The Critical Line 99

5.5.5 Inef¿cient Portfolios 101

5.6 Legitimate Portfolios 102

5.7 ''Unusual'' Graphical Solutions Don't Exist 103

5.8 Representing Constraints Graphically 103

5.9 The Interior Decorator Fallacy 103

5.10 Summary 104

Appendix: Quadratic Equations 105

A5.1 Quadratic Equations 105

A5.2 Analysis of Quadratics in Two Unknowns 106

A5.3 Analysis of Quadratics in One Unknown 107

A5.4 Solving an Ellipse 108

A5.5 Solving for Lines Tangent to a Set of Ellipses 110

CHAPTER 6 Ef¿cient Portfolios 113

6.1 Risk and Return for Two-Asset Portfolios 113

6.2 The Opportunity Set 114

6.2.1 The Two-Security Case 114

6.2.2 Minimizing Risk in the Two-Security Case 116

6.2.3 The Three-Security Case 117

6.2.4 The n-Security Case 119

6.3 Markowitz Diversi¿cation 120

6.4 Ef¿cient Frontier without the Risk-Free Asset 123

6.5 Introducing a Risk-Free Asset 126

6.6 Summary and Conclusions 131

Appendix: Equations for a Relationship between E(rp) and ¿p 131

CHAPTER 7 Advanced Mathematical Portfolio Analysis 135

7.1 Ef¿cient Portfolios without a Risk-Free Asset 135

7.1.1 A General Formulation 135

7.1.2 Formulating with Concise Matrix Notation 140

7.1.3 The Two-Fund Separation Theorem 145

7.1.4 Caveat about Negative Weights 146

7.2 Ef¿cient Portfolios with a Risk-Free Asset 146

7.3 Identifying the Tangency Portfolio 150

7.4 Summary and Conclusions 152

Appendix: Mathematical Derivation of the Ef¿cient Frontier 152

A7.1 No Risk-Free Asset 152

A7.2 With a Risk-Free Asset 156

CHAPTER 8 Index Models and Return-Generating Process 165

8.1 Single-Index Models 165

8.1.1 Return-Generating Functions 165

8.1.2 Estimating the Parameters 168

8.1.3 The Single-Index Model Using Excess Returns 171

8.1.4 The Riskless Rate Can Fluctuate 173

8.1.5 Diversi¿cation 176

8.1.6 About the Single-Index Model 177

8.2 Ef¿cient Frontier and the Single-Index Model 178

8.3 Two-Index Models 186

8.3.1 Generating Inputs 187

8.3.2 Diversi¿cation 188

8.4 Multi-Index Models 189

8.5 Conclusions 190

Appendix: Index Models 191

A8.1 Solving for Ef¿cient Portfolios with the Single-Index Model 191

A8.2 Variance Decomposition 196

A8.3 Orthogonalizing Multiple Indexes 196

PART FOUR Non-Mean-Variance Portfolios

CHAPTER 9 Non-Normal Distributions of Returns 201

9.1 Stable Paretian Distributions 201

9.2 The Student's t-Distribution 204

9.3 Mixtures of Normal Distributions 204

9.3.1 Discrete Mixtures of Normal Distributions 204

9.3.2 Sequential Mixtures of Normal Distributions 205

9.4 Poisson Jump-Diffusion Process 206

9.5 Lognormal Distributions 206

9.5.1 Speci¿cations of Lognormal Distributions 207

9.5.2 Portfolio Analysis under Lognormality 208

9.6 Conclusions 213

CHAPTER 10 Non-Mean-Variance Investment Decisions 215

10.1 Geometric Mean Return Criterion 215

10.1.1 Maximizing the Terminal Wealth 216

10.1.2 Log Utility and the GMR Criterion 216

10.1.3 Diversi¿cation and the GMR 217

10.2 The Safety-First Criterion 218

10.2.1 Roy's Safety-First Criterion 218

10.2.2 Kataoka's Safety-First Criterion 222

10.2.3 Telser's Safety-First Criterion 225

10.3 Semivariance Analysis 228

10.3.1 De¿nition of Semivariance 228

10.3.2 Utility Theory 230

10.3.3 Portfolio Analysis with the Semivariance 231

10.3.4 Capital Market Theory with the Semivariance 234

10.3.5 Summary about Semivariance 236

10.4 Stochastic Dominance Criterion 236

10.4.1 First-Order Stochastic Dominance 236

10.4.2 Second-Order Stochastic Dominance 241

10.4.3 Third-Order Stochastic Dominance 244

10.4.4 Summary of Stochastic Dominance Criterion 245

10.5 Mean-Variance-Skewness Analysis 246

10.5.1 Only Two Moments Can Be Inadequate 246

10.5.2 Portfolio Analysis in Three Moments 247

10.5.3 Ef¿cient Frontier in Three-Dimensional Space 249

10.5.4 Undiversi¿able Risk and Undiversi¿able Skewness 252

10.6 Summary and Conclusions 254

Appendix A: Stochastic Dominance 254

A10.1 Proof for First-Order Stochastic Dominance 254

A10.2 Proof That FA(r) ¿ FB(r) Is Equivalent to EA(r) ¿ EB(r) for Positive r 255

Appendix B: Expected Utility as a Function of Three Moments 257

CHAPTER 11 Risk Management: Value at Risk 261

11.1 VaR of a Single Asset 261

11.2 Portfolio VaR 263

11.3 Decomposition of a Portfolio's VaR 265

11.3.1 Marginal VaR 265

11.3.2 Incremental VaR 266

11.3.3 Component VaR 267

11.4 Other VaRs 269

11.4.1 Modi¿ed VaR (MVaR) 269

11.4.2 Conditional VaR (CVaR) 270

11.5 Methods of Measuring VaR 270

11.5.1 Variance-Covariance (Delta-Normal) Method 270

11.5.2 Historical Simulation Method 274

11.5.3 Monte Carlo Simulation Method 276

11.6 Estimation of Volatilities 277

11.6.1 Unconditional Variance 277

11.6.2 Simple Moving Average 277

11.6.3 Exponentially Weighted Moving Average 278

11.6.4 GARCH-Based Volatility 278

11.6.5 Volatility Measures Using Price Range 279

11.6.6 Implied Volatility 281

11.7 The Accuracy of VaR Models 282

11.7.1 Back-Testing 283

11.7.2 Stress Testing 284

11.8 Summary and Conclusions 285

Appendix: The Delta-Gamma Method 285

PART FIVE Asset Pricing Models

CHAPTER 12 The Capital Asset Pricing Model 291

12.1 Underlying Assumptions 291

12.2 The Capital Market Line 292

12.2.1 The Market Portfolio 292

12.2.2 The Separation Theorem 293

12.2.3 Ef¿cient Frontier Equation 294

12.2.4 Portfolio Selection 294

12.3 The Capital Asset Pricing Model 295

12.3.1 Background 295

12.3.2 Derivation of the CAPM 296

12.4 Over- and Under-priced Securities 299

12.5 The Market Model and the CAPM 300

12.6 Summary and Conclusions 301

Appendix: Derivations of the CAPM 301

A12.1 Other Approaches 301

A12.2 Tangency Portfolio Research 305

CHAPTER 13 Extensions of the Standard CAPM...