Control and applications of chaos

Celso Grebogi; Ying-Cheng Lai; Scott Hayes

doi:10.1142/S021812749700159X

Control and applications of chaos

Celso Grebogi, Ying-Cheng Lai, Scott Hayes

Physics

United States Army Research Laboratory

Research output: Contribution to journal › Article › peer-review

16 Citations (Scopus)

Abstract

This review describes a procedure or stabilizing a desirable chaotic orbit embedded in a chaotic attractor of dissipative dynamical systems by using small feedback control. The key observation is that certain chaotic orbits may correspond to a desirable system performance. By carefully selecting such an orbit, and then applying small feedback control to stabilize a trajectory from a random initial condition around the target chaotic orbit, desirable system performance can be achieved. As applications, three examples are considered: (1) synchronization of chaotic systems; (2) conversion of transient chaos into sustained chaos; and (3) controlling symbolic dynamics for communication. The first and third problems are potentially relevant to communication in engineering, and the solution of the second problem can be applied to electrical power systems to avoid catastrophic events such as the voltage collapse.

Original language	English
Pages (from-to)	2175-2197
Number of pages	23
Journal	International Journal of Bifurcation and Chaos
Volume	7
Issue number	10
DOIs	https://doi.org/10.1142/S021812749700159X
Publication status	Published - Oct 1997

Keywords

unstable periodic-orbits
chua circuit
universal circuit
feedback-control
transient chaos
synchronization
trajectories
attractors
tracking
systems

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abstract = "This review describes a procedure or stabilizing a desirable chaotic orbit embedded in a chaotic attractor of dissipative dynamical systems by using small feedback control. The key observation is that certain chaotic orbits may correspond to a desirable system performance. By carefully selecting such an orbit, and then applying small feedback control to stabilize a trajectory from a random initial condition around the target chaotic orbit, desirable system performance can be achieved. As applications, three examples are considered: (1) synchronization of chaotic systems; (2) conversion of transient chaos into sustained chaos; and (3) controlling symbolic dynamics for communication. The first and third problems are potentially relevant to communication in engineering, and the solution of the second problem can be applied to electrical power systems to avoid catastrophic events such as the voltage collapse.",

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T1 - Control and applications of chaos

AU - Grebogi, Celso

AU - Lai, Ying-Cheng

AU - Hayes, Scott

PY - 1997/10

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N2 - This review describes a procedure or stabilizing a desirable chaotic orbit embedded in a chaotic attractor of dissipative dynamical systems by using small feedback control. The key observation is that certain chaotic orbits may correspond to a desirable system performance. By carefully selecting such an orbit, and then applying small feedback control to stabilize a trajectory from a random initial condition around the target chaotic orbit, desirable system performance can be achieved. As applications, three examples are considered: (1) synchronization of chaotic systems; (2) conversion of transient chaos into sustained chaos; and (3) controlling symbolic dynamics for communication. The first and third problems are potentially relevant to communication in engineering, and the solution of the second problem can be applied to electrical power systems to avoid catastrophic events such as the voltage collapse.

AB - This review describes a procedure or stabilizing a desirable chaotic orbit embedded in a chaotic attractor of dissipative dynamical systems by using small feedback control. The key observation is that certain chaotic orbits may correspond to a desirable system performance. By carefully selecting such an orbit, and then applying small feedback control to stabilize a trajectory from a random initial condition around the target chaotic orbit, desirable system performance can be achieved. As applications, three examples are considered: (1) synchronization of chaotic systems; (2) conversion of transient chaos into sustained chaos; and (3) controlling symbolic dynamics for communication. The first and third problems are potentially relevant to communication in engineering, and the solution of the second problem can be applied to electrical power systems to avoid catastrophic events such as the voltage collapse.

KW - unstable periodic-orbits

KW - chua circuit

KW - universal circuit

KW - feedback-control

KW - transient chaos

KW - synchronization

KW - trajectories

KW - attractors

KW - tracking

KW - systems

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DO - 10.1142/S021812749700159X

M3 - Article

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VL - 7

SP - 2175

EP - 2197

JO - International Journal of Bifurcation and Chaos

JF - International Journal of Bifurcation and Chaos

IS - 10

ER -

Control and applications of chaos

Abstract

Keywords

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