Bifurcation theory of impulsive dynamical systems /

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Bibliographic Details
Author / Creator:Church, Kevin E. M., author.
Imprint:Cham, Switzerland : Springer, [2021]
Description:1 online resource (xvii, 388 pages) : illustrations (some color).
Language:English
Series:IFSR international series in systems science and systems engineering, 1574-0463 ; volume 34
IFSR international series on systems science and engineering ; v. 34.
Subject:
Format: E-Resource Book
URL for this record:http://pi.lib.uchicago.edu/1001/cat/bib/12611466
Hidden Bibliographic Details
Other authors / contributors:Liu, Xinzhi, 1956- author.
ISBN:9783030645335
3030645339
9783030645328
3030645320
9783030645342
3030645347
9783030645359
3030645355
Digital file characteristics:text file PDF
Notes:Includes bibliographical references and index.
Online resource; title from PDF title page (SpringerLink, viewed April 16, 2021).
Summary:This monograph presents the most recent progress in bifurcation theory of impulsive dynamical systems with time delays and other functional dependence. It covers not only smooth local bifurcations, but also some non-smooth bifurcation phenomena that are unique to impulsive dynamical systems. The monograph is split into four distinct parts, independently addressing both finite and infinite-dimensional dynamical systems before discussing their applications. The primary contributions are a rigorous nonautonomous dynamical systems framework and analysis of nonlinear systems, stability, and invariant manifold theory. Special attention is paid to the centre manifold and associated reduction principle, as these are essential to the local bifurcation theory. Specifying to periodic systems, the Floquet theory is extended to impulsive functional differential equations, and this permits an exploration of the impulsive analogues of saddle-node, transcritical, pitchfork and Hopf bifurcations. Readers will learn how techniques of classical bifurcation theory extend to impulsive functional differential equations and, as a special case, impulsive differential equations without delays. They will learn about stability for fixed points, periodic orbits and complete bounded trajectories, and how the linearization of the dynamical system allows for a suitable definition of hyperbolicity. They will see how to complete a centre manifold reduction and analyze a bifurcation at a nonhyperbolic steady state.
Other form:Print version: 9783030645328
Standard no.:10.1007/978-3-030-64533-5

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