Statistical Physics of Spin Glasses and Information Processing An Introduction,9780198509417

Statistical Physics of Spin Glasses and Information Processing An Introduction

by
ISBN13: 9780198509417
ISBN10: 0198509413
Format: Paperback
Pub. Date: 2001-09-27
Publisher(s): Clarendon Press
List Price: $138.66

Buy New

Usually Ships in 5-7 Business Days
$138.52
Add to Cart

Rent Textbook

Select for Price
Add to Cart
There was a problem. Please try again later.

Used Textbook

We're Sorry
Sold Out

eTextbook

We're Sorry
Not Available

Buy from our Marketplace starting at $145.49

How Marketplace Works:

  • This item is offered by an independent seller and not shipped from our warehouse
  • Item details like edition and cover design may differ from our description; see seller's comments before ordering.
  • Sellers much confirm and ship within two business days; otherwise, the order will be cancelled and refunded.
  • Marketplace purchases cannot be returned to eCampus.com. Contact the seller directly for inquiries; if no response within two days, contact customer service.
  • Additional shipping costs apply to Marketplace purchases. Review shipping costs at checkout.

Summary

Spin glasses are magnetic materials. Statistical mechanics, a subfield of physics, has been a powerful tool to theoretically analyse various unique properties of spin glasses. A number of new analytical techniques have been developed to establish a theory of spin glasses. Surprisingly, thesetechniques have turned out to offer new tools and viewpoints for the understanding of information processing problems, including neural networks, error-correcting codes, image restoration, and optimization problems. This book is one of the first publications of the past ten years that provide abroad overview of this interdisciplinary field. Most of the book is written in a self-contained manner, assuming only a general knowledge of statistical mechanics and basic probability theory. It provides the reader with a sound introduction to the field and to the analytical techniques necessary tofollow its most recent developments.

Author Biography

Hidetoshi Nishimori is Professor of Physics at Tokyo Institute of Technology

Table of Contents

Mean-field theory of phase transitionsp. 1
Ising modelp. 1
Order parameter and phase transitionp. 3
Mean-field theoryp. 4
Mean-field Hamiltonianp. 4
Equation of statep. 5
Free energy and the Landau theoryp. 6
Infinite-range modelp. 7
Variational approachp. 9
Mean-field theory of spin glassesp. 11
Spin glass and the Edwards-Anderson modelp. 11
Edwards-Anderson modelp. 12
Quenched system and configurational averagep. 12
Replica methodp. 13
Sherrington-Kirkpatrick modelp. 13
SK modelp. 14
Replica average of the partition functionp. 14
Reduction by Gaussian integralp. 15
Steepest descentp. 15
Order parametersp. 16
Replica-symmetric solutionp. 17
Equations of statep. 17
Phase diagramp. 19
Negative entropyp. 21
Replica symmetry breakingp. 23
Stability of replica-symmetric solutionp. 23
Hessianp. 24
Eigenvalues of the Hessian and the AT linep. 26
Replica symmetry breakingp. 27
Parisi solutionp. 28
First-step RSBp. 29
Stability of the first-step RSBp. 31
Full RSB solutionp. 31
Physical quantitiesp. 31
Order parameter near the critical pointp. 32
Vertical phase boundaryp. 33
Physical significance of RSBp. 35
Multivalley structurep. 35
qEA and qp. 35
Distribution of overlapsp. 36
Replica representation of the order parameterp. 37
Ultrametricityp. 38
TAP equationp. 38
TAP equationp. 39
Cavity methodp. 41
Properties of the solutionp. 43
Gauge theory of spin glassesp. 46
Phase diagram of finite-dimensional systemsp. 46
Gauge transformationp. 47
Exact solution for the internal energyp. 48
Application of gauge transformationp. 48
Exact internal energyp. 49
Relation with the phase diagramp. 50
Distribution of the local energyp. 51
Distribution of the local fieldp. 51
Bound on the specific heatp. 52
Bound on the free energy and internal energyp. 53
Correlation functionsp. 55
Identitiesp. 55
Restrictions on the phase diagramp. 57
Distribution of order parametersp. 58
Non-monotonicity of spin configurationsp. 61
Entropy of frustrationp. 62
Modified [plus or minus]J modelp. 63
Expectation value of physical quantitiesp. 63
Phase diagramp. 64
Existence of spin glass phasep. 65
Gauge glassp. 67
Energy, specific heat, and correlationp. 67
Chiralityp. 69
XY spin glassp. 70
Dynamical correlation functionp. 71
Error-correcting codesp. 74
Error-correcting codesp. 74
Transmission of informationp. 74
Similarity to spin glassesp. 75
Shannon boundp. 76
Finite-temperature decodingp. 78
Spin glass representationp. 78
Conditional probabilityp. 78
Bayes formulap. 79
MAP and MPMp. 80
Gaussian channelp. 81
Overlapp. 81
Measure of decoding performancep. 81
Upper bound on the overlapp. 82
Infinite-range modelp. 83
Infinite-range modelp. 84
Replica calculationsp. 84
Replica-symmetric solutionp. 86
Overlapp. 87
Replica symmetry breakingp. 88
First-step RSBp. 88
Random energy modelp. 89
Replica solution in the limit r [right arrow] [infinity]p. 91
Solution for finite rp. 93
Codes with finite connectivityp. 95
Sourlas-type code with finite connectivityp. 95
Low-density parity-check codep. 98
Cryptographyp. 101
Convolutional codep. 102
Definition and examplesp. 102
Generating polynomialsp. 103
Recursive convolutional codep. 104
Turbo codep. 106
CDMA multiuser demodulatorp. 108
Basic idea of CDMAp. 108
Conventional and Bayesian demodulatorsp. 110
Replica analysis of the Bayesian demodulatorp. 111
Performance comparisonp. 114
Image restorationp. 116
Stochastic approach to image restorationp. 116
Binary image and Bayesian inferencep. 116
MAP and MPMp. 117
Overlapp. 118
Infinite-range modelp. 119
Replica calculationsp. 119
Temperature dependence of the overlapp. 121
Simulationp. 121
Mean-field annealingp. 122
Mean-field approximationp. 123
Annealingp. 124
Edgesp. 125
Parameter estimationp. 128
Associative memoryp. 131
Associative memoryp. 131
Model neuronp. 131
Memory and stable fixed pointp. 132
Statistical mechanics of the random Ising modelp. 133
Embedding a finite number of patternsp. 135
Free energy and equations of statep. 135
Solution of the equation of statep. 136
Many patterns embeddedp. 138
Replicated partition functionp. 138
Non-retrieved patternsp. 138
Free energy and order parameterp. 140
Replica-symmetric solutionp. 141
Self-consistent signal-to-noise analysisp. 142
Stationary state of an analogue neuronp. 142
Separation of signal and noisep. 143
Equation of statep. 145
Binary neuronp. 145
Dynamicsp. 146
Synchronous dynamicsp. 147
Time evolution of the overlapp. 147
Time evolution of the variancep. 148
Limit of applicabilityp. 150
Perceptron and volume of connectionsp. 151
Simple perceptronp. 151
Perceptron learningp. 152
Capacity of a perceptronp. 153
Replica representationp. 154
Replica-symmetric solutionp. 155
Learning in perceptronp. 158
Learning and generalization errorp. 158
Learning in perceptronp. 158
Generalization errorp. 159
Batch learningp. 161
Bayesian formulationp. 162
Learning algorithmsp. 163
High-temperature and annealed approximationsp. 165
Gibbs algorithmp. 166
Replica calculationsp. 167
Generalization error at T = 0p. 169
Noise and unlearnable rulesp. 170
On-line learningp. 171
Learning algorithmsp. 171
Dynamics of learningp. 172
Generalization errors for specific algorithmsp. 173
Optimization of learning ratep. 175
Adaptive learning rate for smooth cost functionp. 176
Learning with queryp. 178
On-line learning of unlearnable rulep. 179
Optimization problemsp. 183
Combinatorial optimization and statistical mechanicsp. 183
Number partitioning problemp. 184
Definitionp. 184
Subset sump. 185
Number of configurations for subset sump. 185
Number partitioning problemp. 187
Graph partitioning problemp. 188
Definitionp. 188
Cost functionp. 189
Replica expressionp. 190
Minimum of the cost functionp. 191
Knapsack problemp. 192
Knapsack problem and linear programmingp. 192
Relaxation methodp. 193
Replica calculationsp. 193
Satisfiability problemp. 195
Random satisfiability problemp. 195
Statistical-mechanical formulationp. 196
Replica-symmetric solution and its interpretationp. 199
Simulated annealingp. 201
Simulated annealingp. 202
Annealing schedule and generalized transition probabilityp. 203
Inhomogeneous Markov chainp. 204
Weak ergodicityp. 206
Relaxation of the cost functionp. 209
Diffusion in one dimensionp. 211
Diffusion and relaxation in one dimensionp. 211
Eigenvalues of the Hessianp. 214
Eigenvalue 1p. 214
Eigenvalue 2p. 215
Eigenvalue 3p. 216
Parisi equationp. 217
Channel coding theoremp. 220
Information, uncertainty, and entropyp. 220
Channel capacityp. 221
BSC and Gaussian channelp. 223
Typical sequence and random codingp. 224
Channel coding theoremp. 226
Distribution and free energy of K-SATp. 228
Referencesp. 232
Indexp. 241
Table of Contents provided by Syndetics. All Rights Reserved.

An electronic version of this book is available through VitalSource.

This book is viewable on PC, Mac, iPhone, iPad, iPod Touch, and most smartphones.

By purchasing, you will be able to view this book online, as well as download it, for the chosen number of days.

Digital License

You are licensing a digital product for a set duration. Durations are set forth in the product description, with "Lifetime" typically meaning five (5) years of online access and permanent download to a supported device. All licenses are non-transferable.

More details can be found here.

A downloadable version of this book is available through the eCampus Reader or compatible Adobe readers.

Applications are available on iOS, Android, PC, Mac, and Windows Mobile platforms.

Please view the compatibility matrix prior to purchase.