Andere Kunden interessierten sich auch für
![Biomathematics: Modelling and Simulation]( "Biomathematics: Modelling and Simulation")
Biomathematics: Modelling and Simulation229,99 €![Complex Matters of the Mind]( "Complex Matters of the Mind")
Complex Matters of the Mind121,99 €![Noise Sustained Patterns: Fluctuations and Nonlinearities]( "Noise Sustained Patterns: Fluctuations and Nonlinearities")
Noise Sustained Patterns: Fluctuations and Nonlinearities117,99 €![Nonlinear Noninteger Order Circuits & Systems - An Introduction]( "Nonlinear Noninteger Order Circuits & Systems - An Introduction")
Nonlinear Noninteger Order Circuits & Systems - An Introduction97,99 €![Modeling Complexity in Economic and Social Systems]( "Modeling Complexity in Economic and Social Systems")
Modeling Complexity in Economic and Social Systems148,99 €![Chaotic Dynamics in Two-Dimensional Noninvertible Maps]( "Chaotic Dynamics in Two-Dimensional Noninvertible Maps")
Chaotic Dynamics in Two-Dimensional Noninvertible Maps232,99 €![Micro Meso Macro: Addressing Complex Systems Couplings]( "Micro Meso Macro: Addressing Complex Systems Couplings")
Micro Meso Macro: Addressing Complex Systems Couplings185,99 €
Interacting chaotic oscillators are of interest in many areas of physics, biology, and engineering. In the biological sciences, for instance, one of the challenging problems is to understand how a group of cells or functional units, each displaying complicated nonlinear dynamic phenomena, can interact with one another to produce a coherent response on a higher organizational level.This book is a guide to the fascinating new concept of chaotic synchronization. The topics covered range from transverse stability and riddled basins of attraction in a system of two coupled logistic maps over partial synchronization and clustering in systems of many chaotic oscillators, to noise-induced synchronization of coherence resonance oscillators. Other topics treated in the book are on-off intermittency and the role of the absorbing and mixed absorbing areas, periodic orbit threshold theory, the influence of a small parameter mismatch, and different mechanisms for chaotic phase synchronization.The biological examples include synchronization of the bursting behavior of coupled insulin-producing beta cells, chaotic phase synchronization in the pressure and flow regulation of neighboring functional units of the kidney, and homoclinic transitions to phase synchronization in microbiological reactors.