Introduction to Probability Models by Ross, Sheldon M. -- Read -- Imperial Library of Trantor

Index

Cover image Title page Table of Contents Copyright Preface

New to This Edition Course Examples and Exercises Organization Acknowledgments

Introduction to Probability Theory

Abstract 1.1 Introduction 1.2 Sample Space and Events 1.3 Probabilities Defined on Events 1.4 Conditional Probabilities 1.5 Independent Events 1.6 Bayes’ Formula Exercises References

Random Variables

Abstract 2.1 Random Variables 2.2 Discrete Random Variables 2.3 Continuous Random Variables 2.4 Expectation of a Random Variable 2.5 Jointly Distributed Random Variables 2.6 Moment Generating Functions 2.7 The Distribution of the Number of Events that Occur 2.8 Limit Theorems 2.9 Stochastic Processes Exercises References

Conditional Probability and Conditional Expectation

Abstract 3.1 Introduction 3.2 The Discrete Case 3.3 The Continuous Case 3.4 Computing Expectations by Conditioning 3.5 Computing Probabilities by Conditioning 3.6 Some Applications 3.7 An Identity for Compound Random Variables Exercises

Markov Chains

Abstract 4.1 Introduction 4.2 Chapman–Kolmogorov Equations 4.3 Classification of States 4.4 Long-Run Proportions and Limiting Probabilities 4.5 Some Applications 4.6 Mean Time Spent in Transient States 4.7 Branching Processes 4.8 Time Reversible Markov Chains 4.9 Markov Chain Monte Carlo Methods 4.10 Markov Decision Processes 4.11 Hidden Markov Chains Exercises References

The Exponential Distribution and the Poisson Process

Abstract 5.1 Introduction 5.2 The Exponential Distribution 5.3 The Poisson Process 5.4 Generalizations of the Poisson Process 5.5 Random Intensity Functions and Hawkes Processes Exercises References

Continuous-Time Markov Chains

Abstract 6.1 Introduction 6.2 Continuous-Time Markov Chains 6.3 Birth and Death Processes 6.4 The Transition Probability Function Pij(t) 6.5 Limiting Probabilities 6.6 Time Reversibility 6.7 The Reversed Chain 6.8 Uniformization 6.9 Computing the Transition Probabilities Exercises References

Renewal Theory and Its Applications

Abstract 7.1 Introduction 7.2 Distribution of N(t) 7.3 Limit Theorems and Their Applications 7.4 Renewal Reward Processes 7.5 Regenerative Processes 7.6 Semi-Markov Processes 7.7 The Inspection Paradox 7.8 Computing the Renewal Function 7.9 Applications to Patterns 7.10 The Insurance Ruin Problem Exercises References

Queueing Theory

Abstract 8.1 Introduction 8.2 Preliminaries 8.3 Exponential Models 8.4 Network of Queues 8.5 The System M/G/1 8.6 Variations on the M/G/1 8.7 The Model G/M/1 8.8 A Finite Source Model 8.9 Multiserver Queues Exercises References

Reliability Theory

Abstract 9.1 Introduction 9.2 Structure Functions 9.3 Reliability of Systems of Independent Components 9.4 Bounds on the Reliability Function 9.5 System Life as a Function of Component Lives 9.6 Expected System Lifetime 9.7 Systems with Repair Exercises References

Brownian Motion and Stationary Processes

Abstract 10.1 Brownian Motion 10.2 Hitting Times, Maximum Variable, and the Gambler’s Ruin Problem 10.3 Variations on Brownian Motion 10.4 Pricing Stock Options 10.5 The Maximum of Brownian Motion with Drift 10.6 White Noise 10.7 Gaussian Processes 10.8 Stationary and Weakly Stationary Processes 10.9 Harmonic Analysis of Weakly Stationary Processes Exercises References

Simulation

Abstract 11.1 Introduction 11.2 General Techniques for Simulating Continuous Random Variables 11.3 Special Techniques for Simulating Continuous Random Variables 11.4 Simulating from Discrete Distributions 11.5 Stochastic Processes 11.6 Variance Reduction Techniques 11.7 Determining the Number of Runs 11.8 Generating from the Stationary Distribution of a Markov Chain Exercises References

Solutions to Starred Exercises

Chapter 1 Chapter 2 Chapter 3 Chapter 4 Chapter 5 Chapter 6 Chapter 7 Chapter 8 Chapter 9 Chapter 10 Chapter 11

Index