Stochastic resonance : a mathematical approach in the small noise limit / Samuel Herrmann...[et al.].
Material type:
TextSeries: Mathematical surveys and monographs ; v 194.Publication details: Providence : American Mathematical Society, c2014.Description: xvi, 189 p. : illustrations ; 27 cmISBN: - 9781470410490 (alk. paper)
- 510MS 23 Am512
| Item type | Current library | Call number | Status | Date due | Barcode | Item holds | |
|---|---|---|---|---|---|---|---|
| Books | ISI Library, Kolkata | 510MS Am512 (Browse shelf(Opens below)) | Available | 135864 |
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Includes bibliographical references and index.
Preface --
Introduction --
1. Heuristics of Noise Induced Transitions --
2. Transitions for time Homogeneous Dynamical Systems with Small Noise --
3. Semiclassical Theory of Stochastic Resonance in Dimension 1 --
4. Large Deviations and Transitions between Meta-Stable states of Dynamical Systems with Small Noise and Weak inhomogeneity --
Appendix A: Supplementary Tools --
Appendix B: Laplace's Method --
Bibliography --
Index
This book presents a mathematical approach to stochastic resonance which is based on a large deviations principle (LDP) for randomly perturbed dynamical systems with a weak inhomogeneity given by an exogenous periodicity of small frequency. Resonance, the optimal tuning between period length and noise amplitude, is explained by optimising the LDP's rate function. The authors show that not all physical measures of tuning quality are robust with respect to dimension reduction. They propose measures of tuning quality based on exponential transition rates explained by large deviations techniques and show that these measures are robust. The book sheds some light on the shortcomings and strengths of different concepts used in the theory and applications of stochastic resonance without attempting to give a comprehensive overview of the many facets of stochastic resonance in the various areas of sciences. It is intended for researchers and graduate students in mathematics and the sciences interested in stochastic dynamics who wish to understand the conceptual background of stochastic resonance.
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