Asymptotic Representation of Relaxation Oscillations in Lasers
Asymptotic Representation of Relaxation Oscillations in Lasers
Springer | Complex Systems | December 8, 2016 | ISBN-10: 3319428594 | 230 pages | pdf | 5.5 mb
Springer | Complex Systems | December 8, 2016 | ISBN-10: 3319428594 | 230 pages | pdf | 5.5 mb
Authors: Grigorieva, Elena V., Kaschenko, Sergey A.
This book presents an analytical method for description of stronly nonlinear relaxation pulsing in laser systems
As a result of asymptotic integration, the original differential system is reduced to a discrete mapping
The method is applied to systems of autonomous and non-autonomous ordinary differential equations, as well as to infinite-dimensional delay-differential systems and to partial differential equations in discrete form of coupled systems
By analyzing fixed points of the mapping, we conclude about the existence of pulse regimes and their bifurcations By studying maps dynamics, we obtain the conditions for multi-rytmicity (coexistence of pulsings), quasiperiodic and chaotic pulsing Describing the control method using a single short-time external impact to a laser system
In this book we analyze relaxation oscillations in models of lasers with nonlinear elements controlling light dynamics. The models are based on rate equations taking into account periodic modulation of parameters, optoelectronic delayed feedback, mutual coupling between lasers, intermodal interaction and other factors.
With the aim to study relaxation oscillations we present the special asymptotic method of integration for ordinary differential equations and differential-difference equations. As a result, they are reduced to discrete maps. Analyzing the maps we describe analytically such nonlinear phenomena in lasers as multistability of large-amplitude relaxation cycles, bifurcations of cycles, controlled switching of regimes, phase synchronization in an ensemble of coupled systems and others.
The book can be fruitful for students and technicians in nonlinear laser dynamics and in differential equations.
Number of Pages
VIII, 230
Number of Illustrations and Tables
73 b/w illustrations
Topics
Theoretical, Mathematical and Computational Physics
Ordinary Differential Equations
Optics, Lasers, Photonics, Optical Devices
Engineering Fluid Dynamics
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