This book provides a general overview of several concepts of synchronization and brings together related approaches to secure communication in chaotic systems. This is achieved using a combination of analytic, algebraic, geometrical and asymptotical methods to tackle the dynamical feedback stabilization problem. In particular, differential-geometric and algebraic differential concepts reveal important structural properties of chaotic systems and serve as guide for the construction of design procedures for a wide variety of chaotic systems. The basic differential algebraic and geometric concepts are presented in the first few chapters in a novel way as design tools, together with selected experimental studies demonstrating their importance. The subsequent chapters treat recent applications. Written for graduate students in applied physical sciences, systems engineers, and applied mathematicians interested in synchronization of chaotic systems and in secure communications, this self-contained text requires only basic knowledge of integer ordinary and fractional ordinary differential equations. Design applications are illustrated with the help of several physical models of practical interest.
Recenzijas
This book provides a general overview of several concepts of synchronization and brings together related approaches to secure communication using chaotic systems. The monograph will be useful to engineers and physicists, graduate students and researchers interested in mathematical modelling, the theory of fractional ordinary differential equations, numerical simulations, synchronization of chaotic systems and secure communications and to everybody interested in mastering the new mathematical methods finding more and more applications. (Paulius Mikinis, Mathematical Reviews, April, 2017)
Control theory and synchronization.- A model-free based proportional
reduced-order observer design for the synchronization of Lorenz system.- A
Model-Free Sliding Observer to Synchronization Problem Using Geometric
Techniques.- Experimental synchronization by means of observers.-
Synchronization of an uncertain Rikitake System with parametric estimation.-
Secure Communications and Synchronization via a Sliding-mode Observer.-
Synchronization and anti-synchronization of chaotic systems: A differential
and algebraic approach.- Synchronization of chaotic Liouvillian systems: An
application to Chuas oscillator.- Synchronization of Partially unknown
Nonlinear Fractional Order
Systems.- Generalized Synchronization via the differential primitive
element.- Generalized synchronization for a class of non-differentially flat
and Liouvillian chaotic systems.- Generalized multi-synchronization by means
of a family of dynamical feedbacks.- Fractional generalized
synchronizationin nonlinear fractional order systems via a dynamical
feedback.- An Observer for a Class of Incommensurate Fractional Order
Systems.- Appendex.- Index.
In this book several concepts of synchronization are generalized and related approaches to secure communication in chaotic systems are merged. This is achieved using a combination of analytic, algebraic, geometrical and asymptotical methods to tackle the dynamical feedback stabilization problem. In particular, differential-geometric and algebraic differential concepts reveal important structural properties of chaotic systems and serve as guide for the construction of design procedures for a wide variety of chaotic systems. The basic differential algebraic and geometric concepts are presented in the first few chapters in a novel way as design tools, together with selected experimental studies revealing their importance. The subsequent chapters treat recent applications. Written for audience of graduate students in applied physical sciences, systems engineers and applied mathematicians interested in synchronization of chaotic systems and in secure communications, this self-contained textrequires only basic knowledge of integer ordinary and fractional ordinary differential equations. Design applications are illustrated with the help of several physical models of practical interest.
