Book contents
- Frontmatter
- Contents
- Preface
- 1 Introduction
- 2 Local central limit theorem
- 3 Approximation by Brownian motion
- 4 The Green's function
- 5 One-dimensional walks
- 6 Potential theory
- 7 Dyadic coupling
- 8 Additional topics on simple random walk
- 9 Loop measures
- 10 Intersection probabilities for random walks
- 11 Loop-erased random walk
- Appendix
- Bibliography
- Index of Symbols
- Index
Preface
Published online by Cambridge University Press: 05 June 2012
- Frontmatter
- Contents
- Preface
- 1 Introduction
- 2 Local central limit theorem
- 3 Approximation by Brownian motion
- 4 The Green's function
- 5 One-dimensional walks
- 6 Potential theory
- 7 Dyadic coupling
- 8 Additional topics on simple random walk
- 9 Loop measures
- 10 Intersection probabilities for random walks
- 11 Loop-erased random walk
- Appendix
- Bibliography
- Index of Symbols
- Index
Summary
Random walk – the stochastic process formed by successive summation of independent, identically distributed random variables – is one of the most basic and well-studied topics in probability theory. For random walks on the integer lattice ℤd, the main reference is the classic book by Spitzer (1976). This text considers only a subset of such walks, namely those corresponding to increment distributions with zero mean and finite variance. In this case, one can summarize the main result very quickly: the central limit theorem implies that under appropriate rescaling the limiting distribution is normal, and the functional central limit theorem implies that the distribution of the corresponding path-valued process (after standard rescaling of time and space) approaches that of Brownian motion.
Researchers who work with perturbations of random walks, or with particle systems and other models that use random walks as a basic ingredient, often need more precise information on random walk behavior than that provided by the central limit theorems. In particular, it is important to understand the size of the error resulting from the approximation of random walk by Brownian motion. For this reason, there is need for more detailed analysis. This book is an introduction to the random walk theory with an emphasis on the error estimates. Although “mean zero, finite variance” assumption is both necessary and sufficient for normal convergence, one typically needs to make stronger assumptions on the increments of the walk in order to obtain good bounds on the error terms.
- Type
- Chapter
- Information
- Random Walk: A Modern Introduction , pp. ix - xiiPublisher: Cambridge University PressPrint publication year: 2010