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E-raamat: Stochastic Processes and Long Range Dependence

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Stochastic Processes and Long Range DependenceSuurem pilt
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This monograph is a gateway for researchers and graduate students to explore the profound, yet subtle, world of long-range dependence (also known as long memory). The text is organized around the probabilistic properties of stationary processes that are important for determining the presence or absence of long memory. The first few chapters serve as an overview of the general theory of stochastic processes which gives the reader sufficient background, language, and models for the subsequent discussion of long memory. The later chapters devoted to long memory begin with an introduction to the subject along with a brief history of its development, followed by a presentation of what is currently the best known approach, applicable to stationary processes with a finite second moment. The book concludes with a chapter devoted to the author"s own, less standard, point of view of long memory as a phase transition, and even includes some novel results.Most of the material in the book ha

s not previously been published in a single self-contained volume, and can be used for a one- or two-semester graduate topics course. It is complete with helpful exercises and an appendix which describes a number of notions and results belonging to the topics used frequently throughout the book, such as topological groups and an overview of the Karamata theorems on regularly varying functions.

Preface.- Stationary Processes.- Ergodic Theory of Stationary Processes.- Infinitely Divisible Processes.- Heavy Tails.- Hurst Phenomenon.- Second-order Theory.- Fractionally Integrated Processes.- Self-similar Processes.- Long Range Dependence as a Phase Transition.- Appendix.

Arvustused

This book is dedicated to the long-range dependence as a property of stationary stochastic processes. It is a very interesting, well-written and easy to read book and can be used as a source of information for students and researchers who want to learn about the long-range dependence property. (Miroslav M. Risti, zbMATH 1376.60007, 2018) The author has achieved a remarkably balanced presentation: the book includes selective materials for a first class on stationary stochastic processes, explains important concepts and key developments for long-range dependence, illustrates with a large collection of important and representative examples, and points out at the end a very promising direction in the area. The monograph is an ideal textbook on stochastic processes with long-range dependence for a one- or two-semester course for graduate students. (Yizao Wany, Mathematical Reviews, October, 2017)

1 Stationary Processes
1(26)
1.1 Stationarity and Invariance
1(4)
1.2 Stationary Processes with a Finite Variance
5(8)
1.3 Measurability and Continuity in Probability
13(2)
1.4 Linear Processes
15(10)
1.5 Comments on
Chapter 1
25(1)
1.6 Exercises to
Chapter 1
25(2)
2 Elements of Ergodic Theory of Stationary Processes and Strong Mixing
27(46)
2.1 Basic Definitions and Ergodicity
27(9)
2.2 Mixing and Weak Mixing
36(17)
2.3 Strong Mixing
53(7)
2.4 Conservative and Dissipative Maps
60(9)
2.5 Comments on
Chapter 2
69(1)
2.6 Exercises to
Chapter 2
70(3)
3 Infinitely Divisible Processes
73(60)
3.1 Infinitely Divisible Random Variables, Vectors, and Processes
73(8)
3.2 Infinitely Divisible Random Measures
81(8)
3.3 Infinitely Divisible Processes as Stochastic Integrals
89(14)
3.4 Series Representations
103(6)
3.5 Examples of Infinitely Divisible Self-Similar Processes
109(11)
3.6 Stationary Infinitely Divisible Processes
120(8)
3.7 Comments on
Chapter 3
128(1)
3.8 Exercises to
Chapter 3
129(4)
4 Heavy Tails
133(42)
4.1 What Are Heavy Tails? Subexponentiality
133(13)
4.2 Regularly Varying Random Variables
146(8)
4.3 Multivariate Regularly Varying Tails
154(13)
4.4 Heavy Tails and Convergence of Random Measures
167(4)
4.5 Comments on
Chapter 4
171(1)
4.6 Exercises to
Chapter 4
172(3)
5 Introduction to Long-Range Dependence
175(18)
5.1 The Hurst Phenomenon
175(7)
5.2 The Joseph Effect and Nonstationarity
182(6)
5.3 Long Memory, Mixing, and Strong Mixing
188(2)
5.4 Comments on
Chapter 5
190(1)
5.5 Exercises to
Chapter 5
190(3)
6 Second-Order Theory of Long-Range Dependence
193(36)
6.1 Time-Domain Approaches
193(4)
6.2 Spectral Domain Approaches
197(19)
6.3 Pointwise Transformations of Gaussian Processes
216(10)
6.4 Comments on
Chapter 6
226(1)
6.5 Exercises to
Chapter 6
227(2)
7 Fractionally Differenced and Fractionally Integrated Processes
229(18)
7.1 Fractional Integration and Long Memory
229(4)
7.2 Fractional Integration of Second-Order Processes
233(9)
7.3 Fractional Integration of Processes with Infinite Variance
242(3)
7.4 Comments on
Chapter 7
245(1)
7.5 Exercises to
Chapter 7
246(1)
8 Self-Similar Processes
247(38)
8.1 Self-Similarity, Stationarity, and Lamperti's Theorem
247(8)
8.2 General Properties of Self-Similar Processes
255(8)
8.3 SSSI Processes with Finite Variance
263(5)
8.4 SSSI Processes Without a Finite Variance
268(5)
8.5 What Is in the Hurst Exponent? Ergodicity and Mixing
273(8)
8.6 Comments on
Chapter 8
281(1)
8.7 Exercises to
Chapter 8
282(3)
9 Long-Range Dependence as a Phase Transition
285(78)
9.1 Why Phase Transitions?
285(2)
9.2 Phase Transitions in Partial Sums
287(5)
9.3 Partial Sums of Finite-Variance Linear Processes
292(8)
9.4 Partial Sums of Finite-Variance Infinitely Divisible Processes
300(12)
9.5 Partial Sums of Infinite-Variance Linear Processes
312(13)
9.6 Partial Sums of Infinite-Variance Infinitely Divisible Processes
325(12)
9.7 Phase Transitions in Partial Maxima
337(6)
9.8 Partial Maxima of Stationary Stable Processes
343(12)
9.9 Comments on
Chapter 9
355(4)
9.10 Exercises to
Chapter 9
359(4)
10 Appendix
363(42)
10.1 Topological Groups
363(1)
10.2 Weak and Vague Convergence
364(5)
10.3 Signed Measures
369(4)
10.4 Occupation Measures and Local Times
373(11)
10.5 Karamata Theory for Regularly Varying Functions
384(13)
10.6 Multiple Integrals with Respect to Gaussian and SαS Measures
397(2)
10.7 Inequalities, Random Series, and Sample Continuity
399(3)
10.8 Comments on
Chapter 10
402(1)
10.9 Exercises to
Chapter 10
403(2)
Bibliography 405(8)
Index 413
Gennady Samorodnitsky is a Professor in the School of Operations Research and Information Engineering at Cornell University. His interest lies both in probability theory and in its various applications.
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