Description
Book SynopsisGame-theoretic probability and finance come of age
Glenn Shafer and Vladimir Vovk's Probability and Finance, published in 2001, showed that perfect-information games can be used to define mathematical probability. Based on fifteen years of further research, Game-Theoretic Foundations for Probability and Finance presents a mature view of the foundational role game theory can play. Its account of probability theory opens the way to new methods of prediction and testing and makes many statistical methods more transparent and widely usable. Its contributions to finance theory include purely game-theoretic accounts of Ito's stochastic calculus, the capital asset pricing model, the equity premium, and portfolio theory.
Game-Theoretic Foundations for Probability and Finance is a book of research. It is also a teaching resource. Each chapter is supplemented with carefully designed exercises and notes relating the new theory to its historical context
Table of Contents
Preface xi
Acknowledgments xv
Part I Examples in Discrete Time 1
1 Borel’s Law of Large Numbers 5
1.1 A Protocol for Testing Forecasts 6
1.2 A Game-Theoretic Generalization of Borel’s Theorem 8
1.3 Binary Outcomes 16
1.4 Slackenings and Supermartingales 18
1.5 Calibration 19
1.6 The Computation of Strategies 21
1.7 Exercises 21
1.8 Context 24
2 Bernoulli’s and De Moivre’s Theorems 31
2.1 Game-Theoretic Expected Value and Probability 33
2.2 Bernoulli’s Theorem for Bounded Forecasting 37
2.3 A Central Limit Theorem 39
2.4 Global Upper Expected Values for Bounded Forecasting 45
2.5 Exercises 46
2.6 Context 49
3 Some Basic Supermartingales 55
3.1 Kolmogorov’s Martingale 56
3.2 Doléans’s Supermartingale 56
3.3 Hoeffding’s Supermartingale 58
3.4 Bernstein’s Supermartingale 63
3.5 Exercises 66
3.6 Context 67
4 Kolmogorov’s Law of Large Numbers 69
4.1 Stating Kolmogorov’s Law 70
4.2 Supermartingale Convergence Theorem 73
4.3 How Skeptic Forces Convergence 80
4.4 How Reality Forces Divergence 81
4.5 Forcing Games 82
4.6 Exercises 86
4.7 Context 89
5 The Law of the Iterated Logarithm 93
5.1 Validity of the Iterated-Logarithm Bound 94
5.2 Sharpness of the Iterated-Logarithm Bound 99
5.3 Additional Recent Game-Theoretic Results 100
5.4 Connections with Large Deviation Inequalities 104
5.5 Exercises 104
5.6 Context 106
Part II Abstract Theory in Discrete Time 109
6 Betting on a Single Outcome 111
6.1 Upper and Lower Expectations 113
6.2 Upper and Lower Probabilities 115
6.3 Upper Expectations with Smaller Domains 118
6.4 Offers 121
6.5 Dropping the Continuity Axiom 125
6.6 Exercises 127
6.7 Context 131
7 Abstract Testing Protocols 135
7.1 Terminology and Notation 136
7.2 Supermartingales 136
7.3 Global Upper Expected Values 142
7.4 Lindeberg’s Central Limit Theorem for Martingales 145
7.5 General Abstract Testing Protocols 146
7.6 Making the Results of Part I Abstract 151
7.7 Exercises 153
7.8 Context 155
8 Zero-One Laws 157
8.1 Lévy’s Zero-One Law 158
8.2 Global Upper Expectation 160
8.3 Global Upper and Lower Probabilities 162
8.4 Global Expected Values and Probabilities 163
8.5 Other Zero-One Laws 165
8.6 Exercises 169
8.7 Context 170
9 Relation to Measure-Theoretic Probability 175
9.1 Ville’s Theorem 176
9.2 Measure-Theoretic Representation of Upper Expectations 180
9.3 Embedding Game-Theoretic Martingales in Probability Spaces 189
9.4 Exercises 191
9.5 Context 192
Part III Applications in Discrete Time 195
10 Using Testing Protocols in Science and Technology 197
10.1 Signals in Open Protocols 198
10.2 Cournot’s Principle 201
10.3 Daltonism 202
10.4 Least Squares 207
10.5 Parametric Statistics with Signals 212
10.6 Quantum Mechanics 215
10.7 Jeffreys’s Law 217
10.8 Exercises 225
10.9 Context 226
11 Calibrating Lookbacks and p-Values 229
11.1 Lookback Calibrators 230
11.2 Lookback Protocols 235
11.3 Lookback Compromises 241
11.4 Lookbacks in Financial Markets 242
11.5 Calibrating p-Values 245
11.6 Exercises 248
11.7 Context 250
12 Defensive Forecasting 253
12.1 Defeating Strategies for Skeptic 255
12.2 Calibrated Forecasts 259
12.3 Proving the Calibration Theorems 264
12.4 Using Calibrated Forecasts for Decision Making 270
12.5 Proving the Decision Theorems 274
12.6 From Theory to Algorithm 286
12.7 Discontinuous Strategies for Skeptic 291
12.8 Exercises 295
12.9 Context 299
Part IV Game-Theoretic Finance 305
13 Emergence of Randomness in Idealized Financial Markets 309
13.1 Capital Processes and Instant Enforcement 310
13.2 Emergence of Brownian Randomness 312
13.3 Emergence of Brownian Expectation 320
13.4 Applications of Dubins–Schwarz 325
13.5 Getting Rich Quick with the Axiom of Choice 331
13.6 Exercises 333
13.7 Context 334
14 A Game-Theoretic Itô Calculus 339
14.1 Martingale Spaces 340
14.2 Conservatism of Continuous Martingales 348
14.3 Itô Integration 350
14.4 Covariation and Quadratic Variation 355
14.5 Itô’s Formula 357
14.6 Doléans Exponential and Logarithm 358
14.7 Game-Theoretic Expectation and Probability 360
14.8 Game-Theoretic Dubins–Schwarz Theorem 361
14.9 Coherence 362
14.10 Exercises 363
14.11 Context 365
15 Numeraires in Market Spaces 371
15.1 Market Spaces 372
15.2 Martingale Theory in Market Spaces 375
15.3 Girsanov’s Theorem 376
15.4 Exercises 382
15.5 Context 382
16 Equity Premium and CAPM 385
16.1 Three Fundamental Continuous I-Martingales 387
16.2 Equity Premium 389
16.3 Capital Asset Pricing Model 391
16.4 Theoretical Performance Deficit 395
16.5 Sharpe Ratio 396
16.6 Exercises 397
16.7 Context 398
17 Game-Theoretic Portfolio Theory 403
17.1 Stroock–Varadhan Martingales 405
17.2 Boosting Stroock–Varadhan Martingales 407
17.3 Outperforming the Market with Dubins–Schwarz 413
17.4 Jeffreys’s Law in Finance 414
17.5 Exercises 415
17.6 Context 416
Terminology and Notation 419
List of Symbols 425
References 429
Index 455
