Iterative methods in combinatorial optimization
By: Lau, Lap Chi.
Contributor(s): Ravi, R | Singh, Mohit.
Material type:
BookSeries: Cambridge texts in applied mathematics.Publisher: Cambridge : Cambridge University Press, 2011Description: xi, 242 p. ; ill., 23 cm.ISBN: 9780521189439.Subject(s): Data processing | Combinatorial optimization | Bipartite Graphs | Generalized Assignment Problem | Spanning Trees | Matroid Intersection | Duality and Min-Max Theorem | Integrality | Graph Matching | Vertex Cove | Discrepancy Theorem | Bin PackingDDC classification: 518.26 Summary: With the advent of approximation algorithms for NP-hard combinatorial optimization problems, several techniques from exact optimization such as the primal-dual method have proven their staying power and versatility. This book describes a simple and powerful method that is iterative in essence and similarly useful in a variety of settings for exact and approximate optimization. The authors highlight the commonality and uses of this method to prove a variety of classical polyhedral results on matchings, trees, matroids, and flows. The presentation style is elementary enough to be accessible to anyone with exposure to basic linear algebra and graph theory, making the book suitable for introductory courses in combinatorial optimization at the upper undergraduate and beginning graduate levels. Discussions of advanced applications illustrate their potential for future application in research in approximation algorithms.
| Item type | Current location | Call number | Status | Date due | Barcode |
|---|---|---|---|---|---|
| Books | 518.26 LAU (Browse shelf) | Available | 034258 |
Includes bibliographical references and index.
With the advent of approximation algorithms for NP-hard combinatorial optimization problems, several techniques from exact optimization such as the primal-dual method have proven their staying power and versatility. This book describes a simple and powerful method that is iterative in essence and similarly useful in a variety of settings for exact and approximate optimization. The authors highlight the commonality and uses of this method to prove a variety of classical polyhedral results on matchings, trees, matroids, and flows. The presentation style is elementary enough to be accessible to anyone with exposure to basic linear algebra and graph theory, making the book suitable for introductory courses in combinatorial optimization at the upper undergraduate and beginning graduate levels. Discussions of advanced applications illustrate their potential for future application in research in approximation algorithms.
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