Book contents
- Frontmatter
- Contents
- List of colour plates
- Preface
- Acknowledgements
- How to read the book
- Part I The phenomenon: complex motion, unusual geometry
- Part II Introductory concepts
- Part III Investigation of chaotic motion
- 5 Chaos in dissipative systems
- 6 Transient chaos in dissipative systems
- 7 Chaos in conservative systems
- 8 Chaotic scattering
- 9 Applications of chaos
- 10 Epilogue: outlook
- Appendix
- Solutions to the problems
- Bibliography
- Index
- Plate section
6 - Transient chaos in dissipative systems
Published online by Cambridge University Press: 05 June 2012
- Frontmatter
- Contents
- List of colour plates
- Preface
- Acknowledgements
- How to read the book
- Part I The phenomenon: complex motion, unusual geometry
- Part II Introductory concepts
- Part III Investigation of chaotic motion
- 5 Chaos in dissipative systems
- 6 Transient chaos in dissipative systems
- 7 Chaos in conservative systems
- 8 Chaotic scattering
- 9 Applications of chaos
- 10 Epilogue: outlook
- Appendix
- Solutions to the problems
- Bibliography
- Index
- Plate section
Summary
Under certain circumstances chaotic behaviour is of finite duration only, i.e. the complexity and unpredictability of the motion can be observed over a finite time interval. Nevertheless, there also exists in these cases a set in phase space responsible for chaos, which is, however, non-attracting. This set is again a well defined fractal, although it is more rarefied than chaotic attractors. This type of chaos is called transient chaos, and the underlying non-attracting set in invertible systems is a chaotic saddle. The concept of transient chaos is more general than that of permanent chaos studied so far, and knowledge of it is essential for a proper interpretation of several chaos-related phenomena. The basic new feature here is the finite lifetime of chaos.
In dissipative systems transient chaos appears primarily in the dynamics of approaching the attractor(s). It is therefore also called the chaotic transient. The temporal duration of the chaotic behaviour varies even within a given system, depending on the initial conditions (see Fig. 6.1 and Section 1.2.2). Despite the significant differences in the individual lifetimes, an average lifetime can be defined. To this end, it is helpful to consider several types of motion (trajectories) instead of a single one: the study of particle ensembles is even more important in transient than in permanent chaos.
- Type
- Chapter
- Information
- Chaotic DynamicsAn Introduction Based on Classical Mechanics, pp. 191 - 226Publisher: Cambridge University PressPrint publication year: 2006