An Introduction to Semiflows Contributor(s): Milani, Albert J. (Author), Koksch, Norbert J. (Author) |
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ISBN: 1584884584 ISBN-13: 9781584884583 Publisher: CRC Press OUR PRICE: $218.50 Product Type: Hardcover - Other Formats Published: October 2004 Annotation: This book provides an accessible introduction to the class of dynamical systems called semiflows, which includes systems defined or modeled by certain types of differential evolution equations (DEEs). Proceeding from a grounding in ordinary differential equations to attractors and inertial manifolds, the authors show how the basic theory of dynamical systems can be extended naturally and applied to study the asymptotic behavior of solutions of differential evolution equations. The material builds in a careful, gradual progression, developing the background needed by newcomers to the field and culminating in a more detailed presentation of the main topics than found in most sources. |
Additional Information |
BISAC Categories: - Mathematics | Differential Equations - General - Mathematics | Linear & Nonlinear Programming - Science | Physics - Mathematical & Computational |
Dewey: 515.352 |
LCCN: 2004055145 |
Series: Monographs and Surveys in Pure and Applied Mathematics |
Physical Information: 1.03" H x 6.48" W x 9.54" (1.55 lbs) 386 pages |
Descriptions, Reviews, Etc. |
Publisher Description: This book introduces the class of dynamical systems called semiflows, which includes systems defined or modeled by certain types of differential evolution equations (DEEs). It focuses on the basic results of the theory of dynamical systems that can be extended naturally and applied to study the asymptotic behavior of the solutions of DEEs. The authors concentrate on three types of absorbing sets: attractors, exponential attractors, and inertial manifolds. They present the fundamental properties of these sets, and then proceed to show the existence of some of these sets for a number of dynamical systems generated by well-known physical models. In particular, they consider in full detail two particular PDEEs: a semilinear version of the heat equation and a corresponding version of the dissipative wave equation. These examples illustrate the most important features of the theory of semiflows and provide a sort of template that can be applied to the analysis of other models. The material builds in a careful, gradual progression, developing the background needed by newcomers to the field, and culminating in a more detailed presentation of the main topics than found in most sources. The authors' approach to and treatment of the subject builds the foundation for more advanced references and research on global attractors, exponential attractors, and inertial manifolds. |