THEORY OF HpS PACES Peter L. Duren Department of Mathematics University of Michigan Ann Arbor, Michigan Academic Press New York and London 1970 COPYRIGH0T 1970, BY ACADEMIPCR ESSI,N C. ALL RIGHTS RESERVED NO PART OF THIS BOOK MAY BE REPRODUCED IN ANY FORM, BY PHOTOSTAT, MICROFILM, RETRIEVAL SYSTEM, OR ANY OTHER MEANS, WITHOUT WRITTEN PERMISSION FROM THE PUBLISHERS. ACADEMIC PRESS, INC. 111 Fifth Avenue, New York, New York 10003 United Kingdom Edition published by ACADEMIC PRESS, INC. (LONDON) LTD. Berkeley Square House, London WlX bBA LIBRAROYF CONGRESS CATALOG CARD NUMBE: 7R4 -1 17092 PRINTED IN THE UNITED STATES OF AMERICA TO MY FATHER William L. Duren PREFACE The theory of HP spaces has its origins in discoveries made forty or fifty years ago by such mathematicians as G. H. Hardy, J. E. Littlewood, I. I. Privalov, F. and M. Riesz, V. Smirnov, and G. Szego. Most of this early work is concerned with the properties of individual functions of class HP, and is classical in spirit. In recent years, the development of functional analysis has stimulated new interest in the HPc lasses as linear spaces. This point of view has suggested a variety of natural problems and has provided new methods of attack, leading to important advances in the theory. This book is an account of both aspects of the subject, the classical and the modern. It is intended to provide a convenient source for the older parts of the theory (the work of Hardy and Littlewood, for example), as well as to give a self-contained exposition of more recent developments such as Beurling’s theorem on invariant subspaces, the Macintyre-Rogosinski- Shapiro-Havinson theory of extremal problems, interpolation theory, the dual space structure of HP with p < 1, HP spaces over general domains, and Carleson’s proof of the corona theorem. Some of the older results are proved by modern methods. In fact, the dominant theme of the book is the interplay of hard” and soft” analysis, the blending of classical and modern tech- “ “ niques and viewpoints. The book should prove useful both to the research worker and to the graduate student or mathematician who is approaching the subject for the first time. The only prerequisites are an elementary working knowledge of real and complex analysis, including Lebesgue integration and the elements of functional analysis. For example, the books (cited in the bibliography) of Ahlfors or Titchmarsh, Natanson or Royden, and Goffman and Pedrick are more than adequate background. Occasionally, particularly in the last few chapters, some more advanced results enter into the discussion, and appropri- ate references are given. But the book is essentially self-contained, and it can serve as a textbook for a course at the second- or third-year graduate level. In fact, the book has evolved from lectures which I gave in such a course at the University of Michigan in 1964 and again in 1966. With the student in mind, I have tried to keep things at an elementary level wherever possible. xi PREFACE xii On the other hand, some sections of the book (for example, parts of Chapters 4,6,7,9, 10, and 12) are rather specialized and are directed primarily to research workers. Many of these topics appear for the first time in book form. In particular, the last chapter, which gives a complete proof of the corona theorem, is for adults only.” “ Each chapter contains a list of exercises. Some of them are straightforward, others are more challenging, and a few are quite difficult. Those in the last category are usually accompanied by references to the literature. Many of the exercises point out directions in which the theory can be extended and applied. Further indications of this type, as well as historical remarks and references, appear in the Notes at the end of each chapter. Two appendices are included to develop background material which the average mathematician cannot be expected to know. The chapters need not be read in sequence. For example, Chapters 8 and 9 depend only upon the first three chapters (with some deletions possible) and upon the first two sections of Chapter 7. Chapter 12 can be read immediately after Chapters 8 and 9. The coverage is reasonably complete, but some topics which might have been included are mentioned only in the Notes, or not at all. Inevitably, my own interests have influenced the selection of material. I wish to express my sincere appreciation to the many friends, students, and colleagues who offered valuable advice or criticized earlier versions of the manuscript. I am especially indebted to J. Caughran, W. L. Duren, F. W. Gehring, W. K. Hayman, J. Hesse, H. J. Landau, A. Macdonald,’ B. Muckenhoupt, P. Rosenthal, W. Rudin, J. V. Ryff, D. Sarason, H. S. Shapiro, A. L. Shields, B. A. Taylor, G. D. Taylor, G. Weiss and A. Zygmund. I am very thankful to my wife Gay, who accurately prepared the bibliog- raphy and proofread the entire book. Renate McLaughlin’s help with the proofreading was also host valuable. In addition, I am grateful to the Alfred P. Sloan Foundation for support during the academic year 19641965, when I wrote the first coherent draft of the book. I had the good fortune to spend this year at Imperial College, University of London and at the Centre d’Orsay, UniversitC de Paris. The scope of the book was broadened as a result of my mathematical experiences at both of these institutions. In 1968-1969, while at the Institute for Ad- vanced Study on sabbatical leave from the University of Michigan, I added major sections and made final revisions. I am grateful to the National Science Foundation for partial support during this period. Peter L. Duren HARMONIC AND SUBHARMONIC FUNCTIONS CHAPTER 1 This chapter begins with the classical representation theorems for certain classes of harmonic functions in the unit disk, together with some basic results on boundary behavior. After this comes a brief discussion of sub- harmonic functions. Both topics are fundamental to the theory of HP spaces. In particular, subharmonic functions provide a strikingly simple approach to Hardy’s convexity theorem and to Littlewood’s subordination theorem, as shown in Sections 1.4 and 1.5. Finally, the Hardy-Littlewood maximal theorem (proved in Appendix B) is applied to establish an important maximal theorem for analytic functions. 1.1. HARMONIC FUNCTIONS Many problems of analysis center upon analytic functions with restricted growth near the boundary. For functions analytic in a disk, the integral means 2 1 HARMONIC AND SUBHARMONIC FUNCTIONS provide one measure of growth and lead to a particularly rich theory with broad applications. A functionf(z) analytic in the unit disk JzI < 1 is said to be of class HP( 0 < p Ia )i f Mp(r,f)r emains bounded as r -+ 1. Thus H" is the class ofc bo unded anacly tic functions in the disk, while H2i s the class of power series a,z" with la,12 < 00. It is convenient also to introduce the analogous classes of harmonic func- tions. A real-valued function u(z) harmonic in IzI < 1 is said to be of class hp (0 < p 5 a)i f Mp(r,u ) is bounded. Since + + ap5 (a b)P5 2P(ap bp), a 2 0, b 2 0, for 0 < p < 00, an analytic function belongs to HP if and only if its real and imaginary parts are both in hP. The same inequality shows that HP and hP are linear spaces. Finally, it is evident that HP3 H4 if 0 < p < q I 00, and likewise for the hP spaces. Any real-valued function u(z) harmonic in IzI < 1 and continuous in 121 I 1 can be recovered from its boundary function by the Poisson integral u(z) = u(reie)= -1 2nP (r, 0 - t)u(e") dt, (1) 2n 0 where I-r2 P(r, 0) = + 1 - 2r cos 8 r2 is the Poisson kernel. Now replace u(e") in the integral (1) by an arbitrary continuous function q(t) with q(0) = ~(27~T)h.e resulting function u(z) is still harmonic in IzI <1, continuous in IzI 1, and has boundary values u(e") = q(t).G eneralizing this idea, one is led to the notion of a Poisson- Stieltjes integral. This is a function of the form 1 u(z> = u(reie>= -1 2=P (r, e - t)d p(t), (2) 2n 0 where p(t) is of bounded variation on [0,2x]. Again, each such function is harmonic in IzI < 1. THEOREM 1 .I.T hefollowingthreeclassesoffunctionsinI zI < 1a reidentical: (i) Poisson-Stieltjes integrals; (ii) differences of two positive harmonic functions; (iii) h'. The proof is based on the HeIly selection theorem, which we now state for the convenience of the reader. (For a proof, see Natanson [l] or Widder [I]. Also, see Notes.) 1.1 HARMONIC FUNCTIONS 3 LEMMA (Helly selection theorem). Let (p,(t)} be a uniformly bounded sequence of functions of uniformly bounded variation over a finite interval [a, b]. Then some subsequence (pJt)} converges everywhere in [a, b] to a function p(t) of bounded variation, and for every continuous function cp(t), PROOF OF THEOREM 1.1. (i)* (ii). Expressing p(t) as the difference of two bounded nondecreasing functions, we see that every Poisson-Stieltjes integral is the difference of two positive harmonic functions. (ii) * (iii). Suppose u(z) = ul(z) - u2(z), where u1 and u2 are positive harmonic functions. Then j2 n + 2n lu(reie)l d8 4 ul(reiBd) 8 u2(reie)d B 0 0 + = 2nL-u,(O) UZ(O)l, so that u E h'. (iii) 3 (i). Given u E h', define Then pr(0) =0, and for 0 = to < t, < ... < t, = 2n, Hence the functions pr(t) are of uniformly bounded variation. By the Helly selection theorem, there is a sequence {r,} tending to 1 for which prn(t)- + p(t), a function of bounded variation in 0 I t 5271. Thus 8 - t)u(r, ei') dt = lim u(r, z) = u(z). n+ al (Here, as always, z = reie.) As a corollary to the proof, we see that every positive harmonic function in the unit disk can be represented as a Poisson-Stieltjes integral with respect to a nondecreasing function p(t). This is usually called the Herglotz representation. The function p(t) of bounded variation corresponding to a given u E h' is 4 1 HARMONIC AND SUBHARMONIC FUNCTIONS essentially unique. Indeed, if P(r, 8 - t) dp(t) = 0, analytic completion gives where y is a real constant. Since we conclude that joz'ein' dp(t) = 0, IZ = 0, 5 1, 52, . Since the characteristic function of any interval can be approximated in I,' by a continuous periodic function, hence by a trigonometric polynomial, this shows that the measure of each interval is zero. Thus dpis the zero measure. 1.2. BOUNDARY BEHAVIOR OF POISSON-STIELTJES INTEGRALS If u(z) is the Poisson integral of an integrable function p(t), then for any point t = 8, where p is continuous, u(z) + cp(f3,) as z +eioO.T his can be generalized to Poisson-Stieltjes integrals : u(z) +p'(8,) wherever p is continu- ously differentiable. Actually, it is enough that p be differentiable ; or, slightly more generally, that the symmetric derivative exist, as the following theorem shows. THEOREM 1.2. Let u(z) be a Poisson-Stieltjes integral of the form (2), where p is of bounded variation. If the symmetric derivative Dp(8,) exists at a point B0, then the radial limit Iim,.+[ u(reieD)e xists and has the value DP(80)- PROOF. We may assume 8, = 0. Set A =Dp(O), and write 1 rlt 1 1 " 1 - - [p(t) - At] - P(r, t) dt. 2n -z Kt 1.2 BOUNDARY BEHAVIOR OF POISSON-STIELTJES INTEGRALS 5 The integrated term tends to zero as r + 1. For 0 < 6 I It1 ln, Hence for each fixed 6 > 0, u(r) - A - I, + 0, where Given E >0, choose 6 >O so small that Then for r sufficiently near 1, as an integration by parts shows. Thus u(r) + A as r + 1, and the proof is complete. Since a function of bounded variation is differentiable almost everywhere, we obtain two important corollaries. COROLLARY 1. Each function u E h' has a radial limit almost everywhere. COROLLARY 2. If u is the Poisson integral of a function p EL', then u(reie) q(8) almost everywhere. 4 By a refinement of the proof it is even possible to show that u(z) tends to Dp(Bo) along any path not tangent to the unit circle. However, we shall arrive at this result (almost everywhere) by an indirect route. For the present, we content ourselves with showing that a bounded analytic function has such a nontangential limit almost everywhere. For 0 < CI < n/2, construct the sector with vertex eie, of angle 2a, symmetric with respect to the ray from the origin through eie. Draw the two segments from the origin perpendicular to the boundaries of this sector, and let SJe) denote the kite-shaped region so constructed (see Fig. 1). " "