An Initiation to Logarithmic Sobolev Inequalities Gilles Royer An Initiation to Logarithmic Sobolev Inequalities SMF/AMS TEXTS and MONOGRAPHS Volume 14 Cours Specialises Numero 5 1999 An Initiation to Logarithmic Sobolev Inequalities Gilles Royer Translated by Donald Babbitt a 0 N American Mathematical Society Societe Mathematique de France Une Initiation aux Inegalites de Sobolev Logarithmiques An Initiation to Logarithmic Sobolev Inequalities Gilles Royer Originally published in French by Society Mathematique de France. Copyright © 1999 Societe Matht matique de France Translated from the French by Donald Babbitt 2000 Mathematics Subject Classification. Primary 60-02; Secondary 35J85, 47B25, 47D07, 60J60, 82C99. For additional information and updates on this book, visit www.anis.org/bookpages/smfanLs-14 Library of Congress Cataloging-in-Publication Data Royer. Gilles. [Initiation aux in4galites de Sobolev logarithmiques. English] An initiation to logarithmic Sobolev inequalities / Gilles Royer ; translated by Donald Babbitt. p. cm. - (SMF/AMS texts and monographs, ISSN 1525-2302 ; v. 14) (Cours specialises, ISSN 1284-6090 ; 5) Includes bibliographical references. ISBN-13: 978-0-8218-4401-4 (alk. paper) ISBN-10: 0-8218-4401-6 (elk. paper) 1. Ergodic theory. 2. Logarithmic functions. 3. Semigroups of operators. 4. Differential inequalities. I. Title. QA313.R6913 2007 515'.48--dc22 2007060798 Copying and reprinting. Individual readers of this publication, and nonprofit libraries acting for them, are permitted to make fair use of the material, such as to copy a chapter for use in teaching or research. Permission is granted to quote brief passages from this publication in reviews, provided the customary acknowledgment of the source is given. Republication, systematic copying, or multiple reproduction of any material in this publication is permitted only under license from the American Mathematical Society. Requests for such permission should be addressed to the Acquisitions Department, American Mathematical Society, 201 Charles Street, Providence, Rhode Island 02904-2294, USA. Requests can also be made by e-mail to reprint-permissionaams. org. © 2007 by the American Mathematical Society. All rights reserved. The American Mathematical Society retains all rights except those granted to the United States Government. Printed in the United States of America. ® The paper used in this book is acid-free and falls within the guidelines established to ensure permanence and durability. Visit the AMS home page at http://vw.ams.org/ 10987654321 12 1110090807 Contents Preface vii Chapter 1. Self-Adjoint Operators 1 1.1. Symmetric operators 1 1.2. Spectral decomposition of self-adjoint operators 8 Chapter 2. Semi-Groups 15 2.1. Semi-groups of self-adjoint operators 15 2.2. Kolmogorov semi-groups 19 Chapter 3. Logarithmic Sobolev Inequalities 37 3.1. The Poincare and Gross inequalities 37 3.2. An application to ergodicity 55 Chapter 4. Gibbs Measures 65 4.1. Generalities 65 4.2. An Ising model with real spin 73 Chapter 5. Stabilization of Glauber- Langevin Dynamics 89 5.1. The Gross inequality and stabilization 89 5.2. The case of weak interactions 95 5.3. Perspectives 101 Appendix A. 105 A.1. Markovian kernels 105 A.2. Bounded real measures 109 A.3. The topology of weak convergence 111 Bibliography 117 V Preface This book contains the material that was essentially covered in a course "de troisieme cycle"' taught during the second semester of the 1996-1997 academic year at the University d'Orleans. The goal of this course was to give an exposition of an example of the use of logarithmic Sobolev inequal- ities coming primarily from two papers by B. Zegarlinski [Zeg9O, Zeg96]. The example is concerned with real spin models with weak interactions on a lattice where one can apply a classic method due to Dobrushin; see no- tably [DobTO]. For these models, we give a proof of the uniqueness of the Gibbs measure by showing the exponential stabilization of the stochastic evolution of an infinite dimensional diffusion process which generalizes the case of the Glauber dynamics for the Ising model. Although these models are technically more complicated than the Ising model, one still uses famil- iar techniques, e.g., using Ito's stochastic integral calculus to construct and study diffusion processes, as well as utilizing the well-known properties of self-adjoint differential operators on iR" and Sobolev and Poincare inequali- ties in their original setting. These models also utilize in a natural way some elegant results on logarithmic Sobolev inequalities such as the Bakry-Emery and Herbst inequalities. Interestingly, these models are simplifications of the Nelson models of Euclidean fields where Gross first introduced logarithmic Sobolev inequalities.2 In this book we introduce in a self-contained manner the basic notions of self-adjoint operators, diffusion processes, and Gibbs measures. The chap- ter on logarithmic Sobolev inequalities is enriched by adding applications to Markov chains so as not to remain in too special a setting. The reader will find indications of some recent applications of logarithmic Sobolev inequal- ities to statistical mechanics at the end of Chapter 5. I would like to thank my colleagues S. Roelly and P. Maheux for very useful discussions as well as the students of the DEA d'Orleans, in particular, G. Salin. Note added to the original Preface. The translation presented here differs from the French original by a small number of corrections. Since the original course was given, logarithmic Sobolev inequalities have been the subject of many articles. We recommend that interested readers consult 'Translator's note: "Un cours de troisieme cycle" is equivalent to an advanced grad- uate course in an American university. 2Translator's note: These are now also called Gross inequalities. vii viii PREFACE [Cor02, OR071, and their bibliographies if they are interested in further study of the subjects treated here. CHAPTER 1 Self-Adjoint Operators We denote by H, a separable complex Hilbert space,' by V a dense linear subspace of H, and by A an operator from D to H. The space V is called the domain of the operator A and is denoted D(A). Unlike bounded operators, 2 in particular, operators on any finite dimensional Hilbert space, simple consideration of the symmetry of operators does not lead to a theorem of spectral decomposition. We will introduce directly the notion of self- adjointness by utilizing spectral conditions based on an expose of P. Cartier at 1'Ecole Polytechnique. 1.1. Symmetric operators Definition 1.1.1. We say that the complex number A is in the resolvent set p(A) of A if (AId-A) is injective, its image (AId-A)V is dense in'H, and if the inverse operator (A Id - A)-' is a bounded operator from (A Id - A)D to H. This operator is then uniquely extended to a bounded operator R,, on H called the resolvent operator. We often abbreviate A - A Id by A - A. Proposition 1.1.2 (Resolvent Equation). . For all A, Ec E p(A) we have: RA-R1, =(A-u)R,RA. Note that the Resolvent Equation implies that {RA} is a commutative family of operators. Definition 1.1.3. We say that A is closed if V is complete for the norm IIII.a = (II0II2 + IIA',II2)1,2. Consider the graph of A: 9A={(1p,ATp)EHxH : 1P ED}. It is obvious that the projection of the graph of A, with the usual product norm H x H, onto D, with the norm HA, is an isometry. Thus it is clear that A is closed if its graph CA is closed in H x H. For a closed operator A one can express the resolvent set p(A) in a simpler way. 'The scalar product is left linear and right anti-linear. 2Recall that an operator B is bounded if there exists a constant M such that )IBIS < MJJxJJ for all x in V. 1
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