This book is devoted to an important branch of the dynamical systems theory : the study of the fine (fractal) structure of Poincare recurrences -instants of time when the system almost repeats its initial state. The authors were able to write an entirely self-contained text including many insights and examples, as well as providing complete details of proofs. The only prerequisites are a basic knowledge of analysis and topology. Thus this book can serve as a graduate text or self-study guide for courses in applied mathematics or nonlinear dynamics (in the natural sciences). Moreover, the book can be used by specialists in applied nonlinear dynamics following the way in the book. The authors applied the mathematical theory developed in the book to two important problems: distribution of Poincare recurrences for nonpurely chaotic Hamiltonian systems and indication of synchronization regimes in coupled chaotic individual systems.
* Portions of the book were published in an article that won the title "month's new hot paper in the field of Mathematics" in May 2004
* Rigorous mathematical theory is combined with important physical applications
* Presents rules for immediate action to study mathematical models of real systems
* Contains standard theorems of dynamical systems theory
This book is devoted to an important branch of the dynamical systems theory : the study of the fine (fractal) structure of Poincare recurrences -instants of time when the system almost repeats its initial state. The authors were able to write an entirely self-contained text including many insights and examples, as well as providing complete details of proofs. The only prerequisites are a basic knowledge of analysis and topology. Thus this book can serve as a graduate text or self-study guide for courses in applied mathematics or nonlinear dynamics (in the natural sciences). Moreover, the book can be used by specialists in applied nonlinear dynamics following the way in the book. The authors applied the mathematical theory developed in the book to two important problems: distribution of Poincare recurrences for nonpurely chaotic Hamiltonian systems and indication of synchronization regimes in coupled chaotic individual systems.
* Some results of the book were published in an article that won the title "month's new hot paper in the field of Mathematics" in May 2004.
* It is a rare book where rigorous mathematical theory is combined with important physical applications.
* The book presents rules for immediate action to study mathematical models of real systems.
* Together with standard theorems of dynamical systems theory, the book contains some not very well known results that became more and more important for applications.
1. IntroductionPart 1: Fundamentals2. Symbolic Systems3. Geometric
Constructions4. Spectrum of Dimensions for RecurrencesPart II:
Zero-Dimensional Invariant Sets5. Uniformly Hyperbolic Repellers6.
Non-Uniformly Hyperbolic Repellers7. The Spectrum for a Sticky Set8.
Rhythmical DynamicsPart III: One-Dimensional Systems9. Markov Maps of the
Interval10. Suspended FlowsPart IV: Measure Theoretical Results11. Invariant
Measures12. Dimensional for Measures13. The Variational PrinciplePart V:
Physical Interpretation and Applications14. Intuitive Explanation15.
Hamiltonian Systems16. Chaos SynchronizationPart VI: Appendices17. Some Known
Facts About Recurrences18. Birkhoff's Individual Theorem19. The SMB
Theorem20. Amalgamation and FragmentationIndex
The authors started to work on the subject in 1997 because of requirements in nonlinear dynamics to find out quantities that could measure different behavior in time in dynamical systems. They introduced and studied fractal dimensions for Poincare recurrences that appeared to be new, useful characteristics of complexity of dynamics. The authors started to work on the subject in 1997 because of requirements in nonlinear dynamics to find out quantities that could measure different behavior in time in dynamical systems. They introduced and studied fractal dimensions for Poincare recurrences that appeared to be new, useful characteristics of complexity of dynamics. The authors started to work on the subject in 1997 because of requirements in nonlinear dynamics to find out quantities that could measure different behavior in time in dynamical systems. They introduced and studied fractal dimensions for Poincare recurrences that appeared to be new, useful characteristics of complexity of dynamics.
Lisainfo e-raamatute kohta