• Produktbild: Portfolio Construction and Analytics
  • Produktbild: Portfolio Construction and Analytics

Portfolio Construction and Analytics Portfolio Construction Analysis With Illustrations Using R Excel

Aus der Reihe Frank J. Fabozzi Series

148,99 €

inkl. gesetzl. MwSt., Versandkostenfrei


Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

11.04.2016

Verlag

John Wiley & Sons Inc

Seitenzahl

624

Maße (L/B/H)

23,5/15,7/3,8 cm

Gewicht

1043 g

Auflage

1. Auflage

Sprache

Englisch

ISBN

978-1-118-44559-4

Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

11.04.2016

Verlag

John Wiley & Sons Inc

Seitenzahl

624

Maße (L/B/H)

23,5/15,7/3,8 cm

Gewicht

1043 g

Auflage

1. Auflage

Sprache

Englisch

ISBN

978-1-118-44559-4

Herstelleradresse

Libri GmbH
Europaallee 1
36244 Bad Hersfeld
DE

Email: gpsr@libri.de

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  • Produktbild: Portfolio Construction and Analytics
  • Produktbild: Portfolio Construction and Analytics
  • Preface xix

    About the Authors xxv

    Acknowledgments xvii

    Chapter 1 Introduction to Portfolio Management and Analytics 1

    1.1 Asset Classes and the Asset Allocation Decision 1

    1.2 The Portfolio Management Process 4

    1.2.1 Setting the Investment Objectives 4

    1.2.2 Developing and Implementing a Portfolio Strategy 6

    1.2.3 Monitoring the Portfolio 8

    1.2.4 Adjusting the Portfolio 9

    1.3 Traditional versus Quantitative Asset Management 9

    1.4 Overview of Portfolio Analytics 10

    1.4.1 Market Analytics 12

    1.4.2 Financial Screening 15

    1.4.3 Asset Allocation Models 16

    1.4.4 Strategy Testing and Evaluating Portfolio Performance 17

    1.4.5 Systems for Portfolio Analytics 20

    1.5 Outline of Topics Covered in the Book 22

    Part One Statistical Models of Risk and Uncertainty

    Chapter 2 Random Variables, Probability Distributions, and Important Statistical Concepts 31

    2.1 What Is a Probability Distribution? 31

    2.2 The Bernoulli Probability Distribution and Probability Mass Functions 32

    2.3 The Binomial Probability Distribution and Discrete Distributions 34

    2.4 The Normal Distribution and Probability Density Functions 38

    2.5 The Concept of Cumulative Probability 41

    2.6 Describing Distributions 44

    2.6.1 Measures of Central Tendency 44

    2.6.2 Measures of Risk 47

    2.6.3 Skew 54

    2.6.4 Kurtosis 55

    2.7 Dependence between Two Random Variables: Covariance and Correlation 55

    2.8 Sums of Random Variables 57

    2.9 Joint Probability Distributions and Conditional Probability 61

    2.10 Copulas 64

    2.11 From Probability Theory to Statistical Measurement: Probability Distributions and Sampling 66

    2.11.1 Central Limit Theorem 70

    2.11.2 Confidence Intervals 71

    2.11.3 Bootstrapping 72

    2.11.4 Hypothesis Testing 73

    Chapter 3 Important Probability Distributions 77

    3.1 Examples of Probability Distributions 79

    3.1.1 Notation Used in Describing Continuous Probability Distributions 79

    3.1.2 Discrete and Continuous Uniform Distributions 80

    3.1.3 Student's t Distribution 82

    3.1.4 Lognormal Distribution 83

    3.1.5 Poisson Distribution 85

    3.1.6 Exponential Distribution 87

    3.1.7 Chi-Square Distribution 88

    3.1.8 Gamma Distribution 90

    3.1.9 Beta Distribution 90

    3.2 Modeling Financial Return Distributions 91

    3.2.1 Elliptical Distributions 92

    3.2.2 Stable Paretian Distributions 94

    3.2.3 Generalized Lambda Distribution 96

    3.3 Modeling Tails of Financial Return Distributions 98

    3.3.1 Generalized Extreme Value Distribution 98

    3.3.2 Generalized Pareto Distribution 99

    3.3.3 Extreme Value Models 101

    Chapter 4 Statistical Estimation Models 106

    4.1 Commonly Used Return Estimation Models 106

    4.2 Regression Analysis 108

    4.2.1 A Simple Regression Example 109

    4.2.2 Regression Applications in the Investment Management Process 114

    4.3 Factor Analysis 116

    4.4 Principal Components Analysis 118

    4.5 Autoregressive Conditional Heteroscedastic Models 125

    Part Two Simulation and Optimization Modeling

    Chapter 5 Simulation Modeling 133

    5.1 Monte Carlo Simulation: A Simple Example 133

    5.1.1 Selecting Probability Distributions for the Inputs 135

    5.1.2 Interpreting Monte Carlo Simulation Output 137

    5.2 Why Use Simulation? 140

    5.2.1 Multiple Input Variables and Compounding Distributions 141

    5.2.2 Incorporating Correlations 142

    5.2.3 Evaluating Decisions 144

    5.3 How Many Scenarios? 147

    5.4 Random Number Generation 149

    Chapter 6 Optimization Modeling 151

    6.1 Optimization Formulations 152

    6.1.1 Minimization versus Maximization 154

    6.1.2 Local versus Global Optima 155

    6.1.3 Multiple Objectives 156

    6.2 Important Types of Optimization Problems 157

    6.2.1 Convex Programming 157

    6.2.2 Linear Programming 158

    6.2.3 Quadratic Programming 159

    6.2.4 Second-Order Cone Programming 160

    6.2.5 Integer and Mixed Integer Programming 161

    6.3 A Simple Optimization Problem Formulation Example: Portfolio Allocation 161

    6.4 Optimization Algorithms 166

    6.5 Optimization Software 168

    6.6 A Software Implementation Example 170

    6.6.1 Optimization with Excel Solver 171

    6.6.2 Solution to the Portfolio Allocation Example 175

    Chapter 7 Optimization under Uncertainty 180

    7.1 Dynamic Programming 181

    7.2 Stochastic Programming 183

    7.2.1 Multistage Models 184

    7.2.2 Mean-Risk Stochastic Models 189

    7.2.3 Chance-Constrained Models 191

    7.3 Robust Optimization 194

    Part Three Portfolio Theory

    Chapter 8 Asset Diversification 203

    8.1 The Case for Diversification 204

    8.2 The Classical Mean-Variance Optimization Framework 208

    8.3 Efficient Frontiers 212

    8.4 Alternative Formulations of the Classical Mean-Variance Optimization Problem 215

    8.4.1 Expected Return Formulation 215

    8.4.2 Risk Aversion Formulation 215

    8.5 The Capital Market Line 216

    8.6 Expected Utility Theory 220

    8.6.1 Quadratic Utility Function 221

    8.6.2 Linear Utility Function 223

    8.6.3 Exponential Utility Function 224

    8.6.4 Power Utility Function 224

    8.6.5 Logarithmic Utility Function 224

    8.7 Diversification Redefined 226

    Chapter 9 Factor Models 232

    9.1 Factor Models in the Financial Economics Literature 233

    9.2 Mean-Variance Optimization with Factor Models 236

    9.3 Factor Selection in Practice 239

    9.4 Factor Models for Alpha Construction 243

    9.5 Factor Models for Risk Estimation 245

    9.5.1 Macroeconomic Factor Models 245

    9.5.2 Fundamental Factor Models 246

    9.5.3 Statistical Factor Models 248

    9.5.4 Hybrid Factor Models 250

    9.5.5 Selecting the "Right" Factor Model 250

    9.6 Data Management and Quality Issues 251

    9.6.1 Data Alignment 252

    9.6.2 Survival Bias 253

    9.6.3 Look-Ahead Bias 253

    9.6.4 Data Snooping 254

    9.7 Risk Decomposition, Risk Attribution, and Performance Attribution 254

    9.8 Factor Investing 256

    Chapter 10 Benchmarks and the Use of Tracking Error in Portfolio Construction 260

    10.1 Tracking Error versus Alpha: Calculation and Interpretation 261

    10.2 Forward-Looking versus Backward-Looking Tracking Error 264

    10.3 Tracking Error and Information Ratio 265

    10.4 Predicted Tracking Error Calculation 265

    10.4.1 Variance-Covariance Method for Tracking Error Calculation 266

    10.4.2 Tracking Error Calculation Based on a Multifactor Model 266

    10.5 Benchmarks and Indexes 268

    10.5.1 Market Indexes 268

    10.5.2 Noncapitalization Weighted Indexes 270

    10.6 Smart Beta Investing 272

    Part Four Equity Portfolio Management

    Chapter 11 Advances in Quantitative Equity Portfolio Management 281

    11.1 Portfolio Constraints Commonly Used in Practice 282

    11.1.1 Long-Only (No-Short-Selling) Constraints 283

    11.1.2 Holding Constraints 283

    11.1.3 Turnover Constraints 284

    11.1.4 Factor Constraints 284

    11.1.5 Cardinality Constraints 286

    11.1.6 Minimum Holding and Transaction Size Constraints 287

    11.1.7 Round Lot Constraints 288

    11.1.8 Tracking Error Constraints 290

    11.1.9 Soft Constraints 291

    11.1.10 Misalignment Caused by Constraints 291

    11.2 Portfolio Optimization with Tail Risk Measures 291

    11.2.1 Portfolio Value-at-Risk Optimization 292

    11.2.2 Portfolio Conditional Value-at-Risk Optimization 294

    11.3 Incorporating Transaction Costs 297

    11.3.1 Linear Transaction Costs 299

    11.3.2 Piecewise-Linear Transaction Costs 300

    11.3.3 Quadratic Transaction Costs 302

    11.3.4 Fixed Transaction Costs 302

    11.3.5 Market Impact Costs 303

    11.4 Multiaccount Optimization 304

    11.5 Incorporating Taxes 308

    11.6 Robust Parameter Estimation 312

    11.7 Portfolio Resampling 314

    11.8 Robust Portfolio Optimization 317

    Chapter 12 Factor-Based Equity Portfolio Construction and Performance Evaluation 325

    12.1 Equity Factors Used in Practice 325

    12.1.1 Fundamental Factors 326

    12.1.2 Macroeconomic Factors 327

    12.1.3 Technical Factors 327

    12.1.4 Additional Factors 327

    12.2 Stock Screens 328

    12.3 Portfolio Selection 331

    12.3.1 Ad-Hoc Portfolio Selection 331

    12.3.2 Stratification 332

    12.3.3 Factor Exposure Targeting 333

    12.4 Risk Decomposition 334

    12.5 Stress Testing 343

    12.6 Portfolio Performance Evaluation 346

    12.7 Risk Forecasts and Simulation 350

    Part Five Fixed Income Portfolio Management

    Chapter 13 Fundamentals of Fixed Income Portfolio Management 361

    13.1 Fixed Income Instruments and Major Sectors of the Bond Market 361

    13.1.1 Treasury Securities 362

    13.1.2 Federal Agency Securities 363

    13.1.3 Corporate Bonds 363

    13.1.4 Municipal Bonds 364

    13.1.5 Structured Products 364

    13.2 Features of Fixed Income Securities 365

    13.2.1 Term to Maturity and Maturity 365

    13.2.2 Par Value 366

    13.2.3 Coupon Rate 366

    13.2.4 Bond Valuation and Yield 367

    13.2.5 Provisions for Paying Off Bonds 368

    13.2.6 Bondholder Option Provisions 370

    13.3 Major Risks Associated with Investing in Bonds 371

    13.3.1 Interest Rate Risk 371

    13.3.2 Call and Prepayment Risk 372

    13.3.3 Credit Risk 373

    13.3.4 Liquidity Risk 374

    13.4 Fixed Income Analytics 375

    13.4.1 Measuring Interest Rate Risk 375

    13.4.2 Measuring Spread Risk 383

    13.4.3 Measuring Credit Risk 384

    13.4.4 Estimating Fixed Income Portfolio Risk Using Simulation 384

    13.5 The Spectrum of Fixed Income Portfolio Strategies 386

    13.5.1 Pure Bond Indexing Strategy 387

    13.5.2 Enhanced Indexing/Primary Factor Matching 388

    13.5.3 Enhanced Indexing/Minor Factor Mismatches 389

    13.5.4 Active Management/Larger Factor Mismatches 389

    13.5.5 Active Management/Full-Blown Active 390

    13.5.6 Smart Beta Strategies for Fixed Income Portfolios 390

    13.6 Value-Added Fixed Income Strategies 391

    13.6.1 Interest Rate Expectations Strategies 391

    13.6.2 Yield Curve Strategies 392

    13.6.3 Inter- and Intra-sector Allocation Strategies 393

    13.6.4 Individual Security Selection Strategies 394

    Chapter 14 Factor-Based Fixed Income Portfolio Construction and Evaluation 398

    14.1 Fixed Income Factors Used in Practice 398

    14.1.1 Term Structure Factors 399

    14.1.2 Credit Spread Factors 400

    14.1.3 Currency Factors 401

    14.1.4 Emerging Market Factors 401

    14.1.5 Volatility Factors 402

    14.1.6 Prepayment Factors 402

    14.2 Portfolio Selection 402

    14.2.1 Stratification Approach 403

    14.2.2 Optimization Approach 405

    14.2.3 Portfolio Rebalancing 408

    14.3 Risk Decomposition 410

    Chapter 15 Constructing Liability-Driven Portfolios 420

    15.1 Risks Associated with Liabilities 421

    15.1.1 Interest Rate Risk 421

    15.1.2 Inflation Risk 422

    15.1.3 Longevity Risk 423

    15.2 Liability-Driven Strategies of Life Insurance Companies 423

    15.2.1 Immunization 424

    15.2.2 Advanced Optimization Approaches 435

    15.2.3 Constructing Replicating Portfolios 437

    15.3 Liability-Driven Strategies of Defined Benefit Pension Funds 438

    15.3.1 High-Grade Bond Portfolio Solution 439

    15.3.2 Including Other Assets 442

    15.3.3 Advanced Modeling Strategies 443

    Part Six Derivatives and Their Application to Portfolio Management

    Chapter 16 Basics of Financial Derivatives 449

    16.1 Overview of the Use of Derivatives in Portfolio Management 449

    16.2 Forward and Futures Contracts 451

    16.2.1 Risk and Return of Forward/Futures Position 453

    16.2.2 Leveraging Aspect of Futures 453

    16.2.3 Pricing of Futures and Forward Contracts 454

    16.3 Options 459

    16.3.1 Risk and Return Characteristics of Options 460

    16.3.2 Option Pricing Models 470

    16.4 Swaps 485

    16.4.1 Interest Rate Swaps 485

    16.4.2 Equity Swaps 486

    16.4.3 Credit Default Swaps 487

    Chapter 17 Using Derivatives in Equity Portfolio Management 490

    17.1 Stock Index Futures and Portfolio Management Applications 490

    17.1.1 Basic Features of Stock Index Futures 490

    17.1.2 Theoretical Price of a Stock Index Futures Contract 491

    17.1.3 Portfolio Management Strategies with Stock Index Futures 494

    17.2 Equity Options and Portfolio Management Applications 504

    17.2.1 Types of Equity Options 504

    17.2.2 Equity Portfolio Management Strategies with Options 506

    17.3 Equity Swaps 511

    Chapter 18 Using Derivatives in Fixed Income Portfolio Management 515

    18.1 Controlling Interest Rate Risk Using Treasury Futures 515

    18.1.1 Strategies for Controlling Interest Rate Risk with Treasury Futures 518

    18.1.2 Pricing of Treasury Futures 520

    18.2 Controlling Interest Rate Risk Using Treasury Futures Options 521

    18.2.1 Strategies for Controlling Interest Rate Risk Using Treasury Futures Options 524

    18.2.2 Pricing Models for Treasury Futures Options 526

    18.3 Controlling Interest Rate Risk Using Interest Rate Swaps 527

    18.3.1 Strategies for Controlling Interest Rate Risk Using Interest Rate Swaps 528

    18.3.2 Pricing of Interest Rate Swaps 530

    18.4 Controlling Credit Risk with Credit Default Swaps 532

    18.4.1 Strategies for Controlling Credit Risk with Credit Default Swaps 534

    18.4.2 General Principles for Valuing a Single-Name Credit Default Swap 535

    Appendix: Basic Linear Algebra Concepts 541

    References 549

    Index 563