Computational Complexity: A Quantitative Perspective

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There has been a common perception that computational complexity is a theory of "bad news" because its most typical results assert that various real-world and innocent-looking tasks are infeasible. In fact, "bad news" is a relative term, and, indeed, in some situations (e.g., in cryptography), we want an adversary to not be able to perform a certain task. However, a "bad news" result does not automatically become useful in such a scenario. For this to happen, its hardness features have to be quantitatively evaluated and shown to manifest extensively. The book undertakes a quantitative analysis of some of the major results in complexity that regard either classes of problems or individual concrete problems. The size of some important classes are studied using resource-bounded topological and measure-theoretical tools. In the case of individual problems, the book studies relevant quantitative attributes such as approximation properties or the number of hard inputs at each length. One chapter is dedicated to abstract complexity theory, an older field which, however, deserves attention because it lays out the foundations of complexity. The other chapters, on the other hand, focus on recent and important developments in complexity. The book presents in a fairly detailed manner concepts that have been at the centre of the main research lines in complexity in the last decade or so, such as: average-complexity, quantum computation, hardness amplification, resource-bounded measure, the relation between one-way functions and pseudo-random generators, the relation between hard predicates and pseudo-random generators, extractors, derandomization of bounded-error probabilistic algorithms, probabilistically checkable proofs, non-approximability of optimization problems, and others. The book should appeal to graduate computer science students, and to researchers who have an interest in computer science theory and need a good understanding of computational complexity, e.g., researchers in algorithms, AI, logic, and other disciplines. · Emphasis is on relevant quantitative attributes of important results in complexity. · Coverage is self-contained and accessible to a wide audience. · Large range of important topics including: derandomization techniques, non-approximability of optimization problems, average-case complexity, quantum computation, one-way functions and pseudo-random generators, resource-bounded measure and topology.

Author(s): Marius Zimand (Eds.)
Series: North-Holland mathematics studies 196
Edition: 1st ed
Publisher: Elsevier
Year: 2004

Language: English
Pages: 1-340
City: Amsterdam; Boston

Content:
Preface
Pages vii-ix
Marius Zimand

Chapter 1 Preliminaries Original Research Article
Pages 1-23

Chapter 2 Abstract complexity theory Original Research Article
Pages 25-50

Chapter 3 Polynomial time, nondeterministic polynomial time, and exponential time Original Research Article
Pages 51-108

Chapter 4 Quantum computation Original Research Article
Pages 109-141

Chapter 5 One-way functions and pseudo-random generators Original Research Article
Pages 143-224

Chapter 6 Optimization problems Original Research Article
Pages 225-316

Appendix A Tail bounds
Pages 317-320

Bibliography
Pages 321-332

Index
Pages 333-340