
This book presents a unified approach to a rich and rapidly evolving research domain at the interface between statistical physics, theoretical computer science/discrete mathematics, and coding/information theory. It is accessible to graduate students and researchers without a specific training in any of these fields. The selected topics include spin glasses, error correcting codes, satisfiability, and are central to each field. The approach focuses on large random instances, adopting a common probabilistic formulation in terms of graphical models. It presents message passing algorithms like belief propagation and survey propagation, and their use in decoding and constraint satisfaction solving. It also explains analysis techniques like density evolution and the cavity method, and uses them to study phase transitions.
This text investigates the mathematical and physical commonalities between statistical physics, information theory, and computational complexity. Authors Marc Mézard and Andrea Montanari, both established researchers in statistical mechanics and complex systems, provide a unified framework for analyzing large random instances. By utilizing graphical models as a common language, the authors demonstrate how techniques from spin glass theory can be applied to solve problems in coding and constraint satisfaction.
What You Will Find
Experts identify this work as a foundational text for graduate students and researchers bridging the gap between physics and computer science. Readers frequently note the high level of mathematical rigor and the clarity with which the authors synthesize disparate research domains.
Page Count:
569
Publication Date:
2009-03-27
Publisher:
Oxford University Press
ISBN-10:
019857083X
ISBN-13:
9780198570837
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