Measure and Integration: A Concise Introduction to Real Analysis

MEASURE AND INTEGRATION A Concise Introduction to Real Analysis

Leonard F. Richardson

@WILEY A JOHN WILEY & SONS, INC., PUBLICATION

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MEASURE AND INTEGRATION

This Page Intentionally Left Blank

MEASURE AND INTEGRATION A Concise Introduction to Real Analysis

Leonard F. Richardson

@WILEY A JOHN WILEY & SONS, INC., PUBLICATION

Copyright C 2009 by John Wiley & Sons, Inc. All rights resened. Published by John Wiley & Sons, Inc.. Hoboken, New Jersey. Published simultaneously in Canada. No part of this publication may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic, mechanical, photocopying, recording, scanning, or otherwise, except as permitted under Section 107 or 108 of the 1976 United States Copyright Act, without either the prior written permission of the Publisher, or authorization through payment of the appropriate per-copy fee to the Copyright Clearance Center, Inc., 222 Rosewood Drive, Danvers, MA 01923. (978) 750-8400, fax (978) 750-4470, or on the web at www.copyright.com. Requests to the Publisher for permission should be addressed to the Permissions Department, John Wiley & Sons, Inc., 11 1 River Street, Hoboken. NJ 07030, (201) 748-601 1. fax (201 ) 748-6008, or online at http:/lwww.wiIey.cornlgoipermission. Limit of Liability/Disclaimer of Warranty: While the publisher and author have used their best efforts in preparing this book, they make no representations or warranties with respect to the accuracy or completeness of the contents of this book and specifically disclaim any implied warranties of merchantability or fitness for a particular purpose. No warranty may be created or extended by sales representatives or written sales materials. The advice and strategies contained herein may not be suitable for your situation. You should consult with a professional where appropriate. Neither the publisher nor author shall be liable for any loss of profit or any other commercial damages, including but not limited to special, incidental, consequential, or other damages. For general information on our other products and services or for technical support. please contact our Customer Care Department within the United States at (800) 762-2974, outside the United States at (3 17) 572-3993 or fax (3 17) 572-4002. Wiley also publishes its books in a variety of electronic formats. Some content that appears in print may not be available in electronic format. For information about Wiley products. visit our web site at www.wiley.com. Library of Congress Cataloging-in-Pi4blication Data:

Richardson, Leonard F. Measure and integration : a concise introduction to real analysis / Leonard F. Richardson. p. cm. Includes bibliographical references. ISBN 978-0-470-25954-2 (cloth) 1 , Lebesgue integral. 2. Measure theory. 3. Mathematical analysis. I. Title. QA312.R45 2008 5 15'.42-d~22 2009009714 Printed in the United States of America 1 0 9 8 7 6 5 4 3 2 1

To Joan, Daniel, and Joseph

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CONTENTS

Preface Acknowledgments

xi ...

Xlll

xv

Introduction

History of the Subject

1

1.1 1.2 1.3

1

History of the Idea Deficiencies of the Riemann Integral Motivation for the Lebesgue Integral

Fields, Borel Fields, and Measures 2.1 2.2 2.3 2.4

Fields, Monotone Classes, and Borel Fields Additive Measures CarathCodory Outer Measure E. Hopf’s Extension Theorem 2.4.1 Fields, a-Fields, and Measures Inherited by a Subset

Lebesgue Measure

3 6 11 11 18 20 24 29

31 vii

viii

CONTENTS

3.1 3.2 3.3

3.4 3.5 3.6

4

Measurable Functions

4.1 4.2 4.3

4.4

5

55 55

56 58 61 63 65 66 69

5.1 5.2

69 72 74 78 81 83 89

5.6

7

Measurable Functions Baire Functions of Measurable Functions 4.1.1 Limits of Measurable Functions Simple Functions and Egoroff’s Theorem 4.3.1 Double Sequences 4.3.2 Convergence in Measure Lusin’s Theorem

31 34 36 38 41 41 43 50 52

The Integral

5.3 5.4 5.5

6

The Finite Interval [ - N , N ) Measurable Sets, Bore1 Sets, and the Real Line 3.2.1 Lebesgue Measure on IR Measure Spaces and Completions Minimal Completion of a Measure Space 3.3.1 3.3.2 A Nonmeasurable Set Semimetric Space of Measurable Sets Lebesgue Measure in Rn Jordan Measure in RTL

Special Simple Functions Extending the Domain of the Integral The Class C+ of Nonnegative Measurable Functions 5.2.1 The Class C of Lebesgue Integrable Functions 5.2.2 5.2.3 Convex Functions and Jensen’s Inequality Lebesgue Dominated Convergence Theorem Monotone Convergence and Fatou’s Theorem Completeness of L’ (X.2,p ) and the Pointwise Convergence Lemma Complex-Valued Functions

92 100

Product Measures and Fubini’s Theorem

103

6.1 6.2 6.3

103 108 117

Product Measures Fubini’s Theorem Comparison of Lebesgue and Riemann Integrals

Functions of a Real Variable

123

CONTENTS

7.1 7.2 7.3 7.4 8

9

10

Functions of Bounded Variation A Fundamental Theorem for the Lebesgue Integral Lebesgue’s Theorem and Vitali’s Covering Theorem Absolutely Continuous and Singular Functions

ix

123 128 131 139

General Countably Additive Set Functions

151

8.1 8.2 8.3

152 156 161

Hahn Decomposition Theorem Radon-Nikodym Theorem Lebesgue Decomposition Theorem

Examples of Dual Spaces from Measure Theory

165

9.1 9.2 9.3 9.4 9.5

165 170 174 178 185

The Banach Space LP(.Y. U, p ) The Dual of a Banach Space The Dual Space of L P ( X .U, p ) Hilbert Space, Its Dual, and L 2 ( X ,U. p ) Riesz-Markov-Saks-Kakutani Theorem

Translation lnvariance in Real Analysis

10.1 10.2

10.3 10.4

10.5

An Orthonormal Basis for L2(T) Closed, Invariant Subspaces of L 2 ( T ) 10.2.1 Integration of Hilbert Space Valued Functions 10.2.2 Spectrum of a Subset of L 2 ( T ) Schwartz Functions: Fourier Transform and Inversion Closed, Invariant Subspaces of L (R) 10.4.1 The Fourier Transform in L (IR) 10.4.2 Translation-Invariant Subspaces of L (R) 10.4.3 The Fourier Transform and Direct Integrals Irreducibility of L 2(R) Under Translations and Rotations 10.5.1 Position and Momentum Operators 10.5.2 The Heisenberg Group

195 196 203 204 206 208 213 213 216 218 219 22 1 222

Appendix: The Banach-Tarski Theorem A.1 The Limits to Countable Additivity

225 225

References

229

Index

231

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PREFACE

The purpose of this textbook is to provide a concise introduction to Measure and Integration, in the context of abstract measure spaces. It is written in the hope that it has sufficient versatility to provide the prerequisites for beginning graduate courses in harmonic analysis, probability, and functional analysis. For both mathematical and pedagogical reasons, it is helpful to the student to emphasize examples and exercises from the real line and Euclidean space. This emphasis also reflects the special theorems that should be established for the cases of the line and Euclidean space. The author's department spans diverse branches of both pure and applied mathematics, making it desirable to teach sufficient measure and integration in one semester. This helps to make room in the introductory part of the graduate curriculum for both complex analysis and functional analysis. The choice of textbook for achieving this goal, covering both abstract measure spaces and Euclidean space in one semester, has been problematic. In 1963, the author was fortunate to be a student in the course "Measure and Integration" taught by Professor Shizuo Kakutani (191 1-2004) at Yale University. His course achieved all the objectives cited above. It also succeeded in conveying to the student a sense of awe for the profound insights the subject has to offer for mathematics.

xi

xii

PREFACE

The author had hoped that a bGok on this subject might be written by Professor Kakutani himself. Since this did not happen, and because the author’s notes from Professor Kakutani’s course seemed potentially useful if converted into a textbook, this book has been written. Many exercises have been added, these being very important to a sound core graduate course in analysis. Several favorite topics in real analysis augment the original course. There are two concluding chapters, intended for the reader who would like to continue this study after the end of the semester. These chapters provide some favorite applications to functional analysis, and to the study of translation-invariant function spaces on the line and the circle. The excursion in the latter direction concludes with a brief proof that L2(IR) is irreducible under the combined actions of translation in the (real) domain, and rotation in the (complex) range, of the functions. There is a very brief introduction to the Heisenberg Commutation Relation and the role of the Heisenberg group in the Stone-von Neumann theorem, which is not proven here. The role of translation invariance in real analysis, beginning with Lebesgue measure and the Lebesgue integral themselves, reflect the author’s interest in the underlying group-theoretic structures in analysis.

AC KNOWLEDGMENTS

Real analysis, and how to teach it, is a perennial topic of discussion among analysis professors, and I have benefited in more ways than I could enumerate from conversations with colleagues for 35 years. I feel that I have benefited in the writing of this book especially from discussions with Professors Jacek Cygan, Mark Davidson, Raymond Fabec, and P. Sundar. It has been a great pleasure and privilege to teach measure and integration to numerous graduate students over the years. They have all contributed to my enjoyment of the subject and to the choices that went into this book. For the autumn semesters of 2007 and 2008, incoming graduate classes at LSU learned measure and integration from a preliminary version of this book. These fine students kindly pointed out numerous typos, and they asked questions that enabled me to improve the exposition. Some found interesting resources in the digital literature. Especially helpful to me were two advanced graduate assistants, Jens Christensen and Anna Zemlyanova. They did a superlative job of grading the weekly homework assignments collected during these two terms, and their observations were especially helpful to me in improving the text. This book began with my own notebook from Professor Shizuo Kakutani’s course in measure theory, taught in 1963 at Yale University. It was Professor Kakutani’s way to leave it to students to write detailed notes for the course, filling in many proofs that were omitted in class. This work was the principal assignment whereby students xiii

xiv

ACKNOWLEDGMENTS

earned academic credit. I have added numerous exercises to the original course, believing these to be essential to the teaching of present-day graduate students. Some exercises require the student to complete a proof or to extend a theorem, thereby incorporating in a formal manner duties of the kind that Professor Kakutani left as an assignment. Many other exercises are problems typical of PhD qualifying examination questions in real analysis. These are intended show students how the subject of measure and integration is used in analysis, and to help them prepare for milestone tests such as qualifiers. No doubt the best features of this text were learned from Professor Kakutani. Also, there are ideas borrowed from several favorite books, which are cited in the References. These are recommended highly for further reading. The supplementary topics in the last chapter, and a number of the exercises in the text, reflect my interest in the role of group actions in analysis, which in this course means mainly the action of the real line or the Euclidean vector group. In this I have benefited from the teaching my own major professor at Yale from 1967 to 1970, Professor George D. Mostow, to whom I am indebted beyond words. The shortcomings and errors of this book are, of course, exclusively my own. I welcome gratefully corrections and suggestions from readers. I am grateful to John Wiley & Sons for the opportunity to offer this book, as well as the course it represents and advocates, to a wider audience. I appreciate especially the role of Ms. Susanne Steitz-Filler, the Mathematics and Statistics Editor of John Wiley & Sons, in making this opportunity available. She and her colleagues provided valued advice, support, and technical assistance, all of which were needed to transform a professor’s course notes into a book. L.F.R.

INTRODUCTI0 N

The reader of this book is likely to be a first-semester graduate student. The author advises this reader, gently but firmly, to expect that what follows is an intense and sustained exercise in logical reasoning. The effort will be great, but the reader may find that the reward is greater and that this subject is an important cornerstone of modern mathematics. Strategies employed commonly by undergraduates for the study of mathematics may not be appropriate for the graduate student. Because the reader is assumed to be a beginning graduate student in mathematics, I offer here some advice regarding how to study mathematics in graduate school. In reading the proofs of theorems in this text or in the study of proofs presented by one’s teacher in class, the student must understand that what is written is much more than a body of facts to be remembered and reproduced upon demand. Each proof has a story that guided the author in its writing. There is a beginning (the hypotheses), a challenge (the objective to be achieved), and a plan that might, with hard work, skill, and good fortune, lead to the desired conclusion. Thus each step of a proof should be seen by the student as meaningful and purposeful, and not as a procedure that is being followed blindly. It will take time and concerted effort for the student to learn to think about the statements and proofs of the presented theorems in this light. Such practice will cultivate the ability to do the exercises as well in a fruitful manner. With experience in recognizing the story of the proof or problem at hand, the student will xv

xvi

INTRODUCTION

be in a position to develop his or her own technique through the work done in the exercises. The first step, before attempting to read a proof, is to read the statement of the theorem carefully, trying to get an overall picture of its content. The student should make sure that he or she knows precisely the definition of each term used in the statement of the theorem. Without that information, it is impossible to understand even the claim of the theorem, let alone its proof. If a term or a symbol in the statement of a theorem or exercise is not recognized, look in the index! Write down what you find. After clarifying explicitly the meaning of each term used, if the student does not see what the theorem is attempting to achieve, it is often helpful to write down a few examples to see what difficulties might arise, leading to the need for the theorem. Working with examples is the rnatheniatical equhlalent of laboratop work for a natural scientist. Indeed, the student should accumulate a tool kit of examples that illustrate what may go wrong with a theorem if the hypotheses are not satisfied. One also should learn examples that show why stronger conclusions than those stated may fail to be valid with the given hypotheses. Many exercises in the text are intended to provide examples that assist one in these ways to grasp the meaning of the theorems, and the student must understand that the exercises are a very important component of the study of measure and integration. The experience gained from the exercises will help the student to understand which steps in the solution of a problem require careful justification.

CHAPTER 1

HISTORY OF THE SUBJECT

1.1 HISTORY OF THE IDEA In a broad sense, much of mathematics is devoted to the decomposition, or analysis, of a whole entity into its component parts and the reconstruction, or synthesis, of the whole from its parts. There is in this an expectation that the whole is somehow equal to the sum of its parts, which are simpler individually. We discuss briefly a few examples of this aspect of mathematics. It was nearly three thousand years ago that Babylonian astronomers successfully predicted the times of lunar and solar eclipses by expressing these complicated events as summations of numerous simpler periodic events. The predictions were fairly accurate, to the extent of predicting eclipses that would be visible at least from some part of the world. That remarkable achievement may be interpreted as the first appearance on Earth of harmonic (or Fourier) analysis. Measurement has been a special interest for mathematicians and scientists since the early days of civilization. Two thousand years ago, the classical geometers of Greece made profound contributions to the study of measurement. A line segment could be measured by a shorter segment if the short one could be laid off end to end in such a way that the long segment would be seen to be an exact positive integer Measure and Integration: A Concise Introduction to Real Aiiulysis. By Leonard F. Richardson Copyright @ 2009 John Wiley & Sons, Inc.

1

2

HISTORY OF THE SUBJECT

multiple of the short one. Two segments were called commensurable if both could be measured by a common shorter segment, or unit of length. And the discovery by Pythagoras or his associates of incommensurable segments was a momentous event in the history of mathematics. Inherent in the definition Greek geometers used for measurement of segments was the concept that the measure of the whole segment must be the sun1 of the measures of its nonoverlapping parts, as indicated by the lengths marked off according to the shorter segment. The Greek geometers pushed this technique much farther, successfully studying the circumference and area of a circle and the surface area and volume of a sphere. These challenges were met by the application of what is called the principle of e.uhaustion. The method was to approximate a geometrical measurement from below, and at each successive iteration of the approximation technique, at least of half of what remained to be counted was to be included. (Greek geometers understood that if too little were taken at each stage, even an endless succession of steps might not approach the goal.) For example, the area of a circle is approximated from within by means of an inscribed 2 '"sided regular polygon. As n increases, the area of the resulting 2n-sided polygon grows in a computable manner. (See Figure 1.1.) We begin with an inscribed square consuming the bulk of the area of the circle. The next polygon is an octagon, which adds the areas of four thin triangles to that of the square. At each stage, one can construct the 2 n+l-gon by bisecting the arcs that are

Figure 1.1 Area of a circle by exhaustion.

subtended by the sides of the inscribed 21L-gon.In effect, the ( n + 1)th stage of the approximation results from adding a small increment to what was obtained at the nth stage. Such classical achievements in geometry may have been the first instances in

DEFICIENCIES OF THE RIEMANN INTEGRAL

3

which a measure (of area, for example) was sought that would be countflb~y addirive, meaning that the measure of the whole slzould be the sum of the measures of its infinite sequence of nonoverlapping parts. Greek geometers and philosophers may not have been entirely convinced of the validity of the principle of exhaustion. The expression of some dissatisfaction with this geometric technique may have been the purpose of the famous paradox of Zeno, in which the legendary warrior Achilles was pitted unsuccessfully in a footrace with a persistent tortoise. The notion that the whole should be the sum of even an infinite sequence of its nonoverlapping parts appears very strongly in modem analysis, both pure and applied. For example, in 1822 Joseph Fourier presented a seminal paper on the heat equation to the French Academy, in which he introduced the use of infinite trigonometric series for the purpose of determining the solution of the heat equation on a finite interval, or rod [6]. Fourier’s method required that the hypothetical solution function be expressible as the sum of an infinite trigonometric series:

Unfortunately, these so-called Fourier series can diverge for very large sets of numbers .z in the domain of even a rather nice function f. Yet, if one ignored the embarrassing reality that f ( z ) need nor be the sum of its parts, Fourier’s method actually worked. And the search was on for suitable concepts and tools to analyze correctly the right classes of functions for which the Fourier series would converge in a useful sense to the functions being represented. The efforts took place on a grand scale. Even the theory of sets was invented by Georg Cantor for the purpose of analyzing sets of convergence and divergence of Fourier series. Though Cantor’s approach was not sufficient for the needs of Fourier series, it became a cornerstone of modern mathematics. Early in the twentieth century Henri Lebesgue invented his new and very refined concept of the integral, based on the measure of suitable subsets of the line. Lebesgue measure became the foundation not only for Fourier analysis, but also for probability, and for functional analysis which permeates modern analysis.

1.2 DEFICIENCIES OF THE RIEMANN INTEGRAL The Riemann integral is the integral of elementary calculus. It is the integral developed intuitively by Newton and Leibnitz and put to great use in the classical sciences. Before undertaking the considerable work of developing the Lebesgue integral, the reader and student need to become acquainted with the deficiencies of the Riemann integral. This will motivate the effort that follows. First, we review the definition of the Riemann integral of a bounded real-valued function f on a closed, finite interval [u. b] of the real line.

4

HISTORY OF THE SUBJECT

Definition 1.2.1 A partition P is an ordered list of finitely many points starting with a and ending with b > a. Thus P = ( ~ 0 . ~ 1. ,. ,.x,}, where a = xo

< x1
0. Here we use the fact that the union of countably many countable sets is countable. For the equality (i) we have used the properties of absolutely convergent double-series ” with respect to summation first by rows and then by columns, or vice versa. This is sufficient to prove (3). Next, we must show that p* is an extension of p and that U is contained within the family of p*-measurable sets. a. We will show that for all A E U, we have p*(A) = ~ ( ~ 4 What ) . is clear is that since A E A u 0 u 0 u . . . we must have p*(A) 6 p(A). In order to prove the opposite inequality, we will make use of the hypothesis of countable additivity 017 U, as in Definition 2.2.2. So, suppose we have a countable covering of A: A c A,, with each A, E U. We can construct from this covering a countable disjoint covering by sets B,E U defined as follows: Let B1 = A1 n A,Bz = (A2 n A)\B1, and in general

u,:

Now A is covered by a countable disjoint family of sets B,E U. Countable additivity on U tells us that

i=l

i=l

for all countable covers by sets A,, where we are using the monotonicity of p . Therefore, p(A) < p*(A). Hence p(A) = p*(A). b. Since we know that p* is a CarathCodory outer measure, we can denote by PI * the family of all p*-measurable sets, as in Definition 2.3.2. We know that U * is a a-field. If we can show that U E U*, then we will know that p* is an extension of p, and it will follow also that B(0)C U*. So, we let A E U. and we let 14’ E Cp(X).According to Definition 2.3.2, we must prove that p * ( \ \ ’ ) = p*(I\’ n A)

+ p*(It’ n A ” )

Because of subadditivity of p * , it will suffice to prove that

p*(I\’) 2 p * ( \ l ’ n A) + / / * ( I t ’ n A‘) ”A doirble series is a sum of the forrn&N,JcN x , , ~and . absolute convergence implies that

which the reader can find in many advanced calculus texts, such as [20]. This is also a special case of Fubini’s Theorem, which is Theorem 6.2.2 in the present text.

E. HOPF'S EXTENSION THEOREM

This inequality would be immediate if p * ( W ) p * ( W ) < a.

=

co, so we will assume that

To this end, we let E > 0. There exist A , E U such that H' E

Note that

27

ULEN A, and

r

and p * ( W n A") 6

xtLlp(Al n A'). Thus r

p*(W7 n A )

+ p*(W n A") 6 2 p ( A Z )< p*(TV) + E , i=l

using absolute convergence of the series and finite additivity of p on U. Since E > 0 is arbitrary, the proof is complete except for uniqueness, which is treated in Exercise 2.2 1.

Definition 2.4.1 A Carathtodory outer measure p defined on q ( X )is called regular with respect to a field U E q ( X ) if and only if for each A E q(X)there exists a Bore1 set B E B(U) such that A c B and p ( A ) = p ( B ) . ' * We turn our attention next to the questions of the uniqueness and regularity of the extension.

EXERCISES 2.19 Let p be afinite, finitely additive measureI9 on a field U 5 q ( X ) . Prove" that p is countably additive on U if and only if for each decreasing sequence A1

with

(-):=1

An = ,@, we have

3 A2 3 . . . 3 A,, 2

...

p ( A T L=) 0.

2.20 The Carathtodory outer measure on ? ( X ) , constructed in Theorem 2.4.1, is regular. Hint: Let A E q ( X ) . For each n E IN pick

I8See Exercise 2.20. 19Finiteness of the measure means that p ( X ) < tm. ?OVariations on this exercise appear in Exercises 5.20. 5.24, and 8.10

28

FIELDS, BOREL FIELDS, AND MEASURES

with each An,t E U, for which p * ( B n ) < p * ( A )+

i.

2.21 Suppose that both p1 and p2 are countably additive extensions of the measure p from the field U to IB(Q). Suppose that p is countably additive on 2. a) Suppose that p ( X ) < a.Prove that p l ( B ) = p2(B) for all B E IB(Q). (Hint: Show that the set

is closed under complementation and under taking unions of increasing sequences, making B(U) a monotone class that contains Q. The finiteness of p ( X ) will be helpful for complementation.) b) Now replace the hypothesis that p ( X ) < co in part (a) with the hypothesis that p is o-finite on X . Prove that p l ( B ) = p 2 ( B ) for all B E IB(U). (Hint: Use Corollary 2.4.1 .)

Theorem 2.4.2 Let p be a regular Carathe'odory outer measure on ' p ( X )such that p ( X ) < c;c. Then a subset A c X is p-mensurable ifand only i f

A X ) = P(A)+ P(4". Proof: Necessity is immediate, so we will prove sufficiency. We need to prove for each IV E ' p ( X )that p ( W ) = p(I1.. n A )

+ p(TV n A').

Because of regularity, there exists a measurable set V 2 It; such that p( V) Observe that, since V is measurable, we have

= ,u(LV).

+

p ( A ) = p ( A n V) p ( A n V c ) . p ( A C )=p(A' n V )+ p ( A c n Vc). By hypothesis and by Equations (2.5),

P ( X ) = P(A) + A A C )= P(V) + P(VC) = [ p ( An V) p(ACn V ) ] [ p ( An V c ) p(ACn V ' ) ] .

+

+

+

On the other hand, it follows from subadditivity that

+ +

p ( A n V) p(Ac n V) 2 p(V), p ( A n V c ) p ( A Cn Vc) 3 p(V'). It follows that

p ( A n V)+ p( Ac n V) = p(V). p ( A n Vc)+ p ( A Cn 11') = p(Vc).

(2.5)

E. HOPF'S EXTENSIONTHEOREM

29

By the choice of V and by the preceding equations,

+

~ ( 1 5 ' )= p ( V ) = p ( V n A) p(V n A") 2 p(lV n A) ~ ~ ( 1n 1 'A") 2 ,L(lV).

+

Hence

p(W n A) + p(11'

n A") = p(117).

and A is measurable. 2.4.1

Fields, a-Fields, and Measures Inherited by a Subset

In Definition 3.3.1, we will see that a triplet, (X.U.p ) , is called a meamre space. provided that X is a set, U E p ( X ) is a a-field, and ,LL is a countably additive measure defined on U.

Definition 2.4.2 A triplet (X,U. p ) is a premeasure space provided that X is a set, Q 2 p ( X ) is a field, and p is a finitely additive measure defined on U. Thus the Hopf Extension Theorem provides necessary and sufficient conditions for a premeasure space to be extended to a full-fledged measure space. Note that there exist premeasure spaces that cannot be extended to measure spaces. 2' It is often useful to consider the restriction of a measure p , given to us in either a premeasure space or a measure space, to a subfield of the power set p ( S ) for some set S E U. An especially important instance is the situation in which ( X .U. p ) is a-finite, so that X = U Z E I N Xwith L , p(X,) < cc,for each i E IN.

Definition 2.4.3 If (X,U. p ) is any premeasure space, define the premeasure space inherited by S E U to be the triplet

(S.Us. P I . where US= {A n S I A E

a} c p(S).

and we retain the symbol p for the restriction to USof the given measure on U. Since U is a field, it is clear that Us E U, so that p is defined on Us. Moreover. it is easily checked that USis itself a subfield of the field p(S), with the understanding that complementation in USwill be with respect to the S, not with respect to X . That is, for A E US,we define A" = S\A. Again, because U is a field, the set S" also inherits a premeasure space from (X,U, p ) .

"For example, see Exercise 2.16

30

FIELDS, BOREL FIELDS, AND MEASURES

Theorem 2.4.3 r f ( X .U. p) is a n j premeasure space and i f S E U, then an a r b i t r a p set B belongs to B(U) if and only if B = B1 u B2, where B1 E B(U.7) and Bz E B(Usc). We are to understand in this theorem that B(Us) E p(S).That is, we treat S as the universal set in the definition of the Borel field generated by US. We observe that if '23 is a a-field in Y ( X )containing 2,then both of the following two conditions are met: '23sis a a-field in p(S)containing US,and '23s. is a a-field in p(S') containing Us.. Conversely, if '231 is a a-field in p ( S ) containing US and if 9 3 2 is a a-field in q ( S " )containing Us., then we define

Proof:

'23

=

(B1 u B2 1 B1

E '231. B2 E ' 2 3 2 ) .

Then it is clear that '23s = and '23s. = 2 3 2 , and that '23 is a a-field in p ( X ) containing U. The conclusion follows from Definition 2.1.5, in which the Borel field generated by a given field is the intersection of all a-fields containing the given field. We note that the preceding theorem does not involve

(X. U), which is called a premeasurable space.

and relates only to the pair

Corollary 2.4.1 Suppose

x = UZEINX'. with each X ,

E U, ajield

contained in p ( X ) . Then B

E

B(U)ifand only if

This is a countable adaptation of the proof of Theorem 2.4.3. The reader should check the details in the same manner as for that theorem. A set 93 is a o-field containing U if and only if the following condition is met for each i E IN: ' 2 3 , ~ ~2 ax,, with 23x,being a a-field in p ( X , ) .

Proof:

CHAPTER 3

LEBESGUE MEASURE

3.1 THE FINITE INTERVAL [ - N , N ) Let XN = [-N, N )c R,a left-closed, right-open finite interval. Denote an interval [ a k , b k ) by J k . We will call a set E = UE=l J k an elementary ser in X , y , provided that

-N 6 a1 6 bl 6 a2 6 b2 6 . . . 6 a,, 6 b, < N . and we will denote by (E the field of such elementary sets in X N . The choice of left-closed, right-open intervals may appear to be very restrictive, but this choice makes ‘2 easily into a field. And it is not a limitation in the long nin, since we will show soon that each singleton (x} turns out to be a Borel set in X N , and thus every interval is a Borel set in X.V. Moreover, we will extend the study of Lebesgue measure to all of lR by means of 0-finiteness. By Exercise 2.13, we can define a finitely additive measure p on (E by the formula

Measure arid 1nregratiort: A Concise htrroducrioti ro Real Analysis. By Leonard E Richardson Copyright @ 2009 John Wiley & Sons, Inc.

31

32

LEBESGUE MEASURE

for each E E E. Then p ( X , v ) = 2 5 . Since this is a finite total measure, a e will apply the result of Exercise 2.19 to prove in the next theorem the extendability of p to a countably additive measure on E3(E). Note that /L is simply the extension to the field generated by intervals J k of the measure that is Euclidean length on each interval J k .

Theorem 3.1.1 Let E be thejeld of disjoitit unions offinitely man) intenwls J k = [ a k . b k ) in [ - N . N ) , as described above. There is a countably additive meusitre 1-1 * defined oti E3( E) that coincides with the measirre p on E, where p of an interval is its Euclidean length. Proof: By the Hopf Extension Theorem, Theorem 2.4.1, it is sufficient to prove that p is countably additive 011 E. By Exercise 2.19, it suffices to show that for each decreasing sequence of elementary sets

El 2 E2

2 . . . 3 El, 2

...

n,:=,

such that En = 0, we have p(E,)= 0. If this were false, then there would exist 6 > 0 such that p(E,) 2 6 for all n E IS.For each n E IN, we can pick an elementary set EA, the closure EA of which is a compact set” I?:, c E,,, and such that

p(En\R)
0. Thus we can construct En so that its closure will be closed In both the topology of IR and the relative topology of [-iV. N ) .

THE FINITE INTERVAL [-lv. 2%')

33

Thus K 71=1

n=l

for all Ii' E W. Yet we know that

-V].By thefinite intersection But each EL is a closed subset of the compact set [-A\r, property (Exercise 3.1) for compact spaces, this is impossible. Since the hypotheses of the Hopf Extension Theorem are satisfied, there is a countably additive measure I , the restriction of p * to the p*-measurable sets in ~ ( X N that ) , extends the concept of the length of an interval. The measure 1 is called Lebesgue measure, and its domain is the set of all Lebesgue measurable sets in X V . H

We have constructed a Lebesgue measure for X , v for each AT E K. It is important to note that the Lebesgue measure defined on X N is the restriction to [ - N , N ) of the Lebesgue measure defined on X , V ~for each N' > N . This follows from Theorem 2.4.3 concerning the Borel field inherited by a subset and from Exercise 2.21 establishing the uniqueness of the Hopf extension measure for g-finite measure spaces. We saw in Exercise 2.20 that the outer measure constructed in the Hopf Extension Theorem (Theorem 2.4.1) is regular. This means that every set S E p ( X ) is a subset of a Borel set B E B(U) having the same measure as the outer measure of S. We apply these concepts to Lebesgue measure constructed in the present section on the interval [-N. N ) . The field of elementary sets (E c B((E)c C. where we use the letter C to denote the family of all measuruble sets in the case of Lebesgue measure.

EXERCISE

3.1 A topological space X is called compact provided that it has the Heine-Bore1 property: Every open covering of X has a finite subcover. a) Suppose X is compact and 3 is a family of closed subsets of X such that

Prove that there is a finite subcollection of 3 with empty intersection. b) Prove thefinite intersection properQ for compact sets: If every intersection of finitely many members of 3 is nonempty, then

34

LEBESGUE MEASURE

3.2 MEASURABLE SETS, BOREL SETS, AND THE REAL LINE The following theorem is concerned with abstract measures on sets, as constructed using the Hopf Extension Theorem. We should recall Exercise 2.20, which tells us that if a countably additive measure 1-1is generated by the Hopf Extension Theorem from a finitely additive measure p on a field 2, then the outer measure p * is regular in the following sense: For each set S E p ( X ) ,there is a Borel set B E B(Q)such that p * ( S ) = p ( B ) .

Theorem 3.2.1 Let p be a finite, countably additive measure, constructed from some finitely additive measure on afield in 2l c ! J ? ( X )using , the Hopf Extension Theorem (2.4.1). Then a set S in p ( X )is measurable23ifandonly ifthere exist Bore1 sets B, and B* in B(U) such that

B, C S

C

B* and p(B,)

= p*(S) = p(B*).

where p* is the outer measure defined on !J?(X ) , as in the proof of the Hopf Exterision Theorem. Proof: We begin with necessity. Suppose that S is measurable. Then we know that p(S) p(Sc) = p ( X ) . Because p is regular, there exists a Borel set B* 2 S such that p ( S ) = p ( B * ) .We know that the measurable sets form a a-field, so S" is measurable too. So there exists a Borel set B 2 S" such that p ( S c ) = p(B). If we let B, = B", then B, c S and p ( B * ) = p(S). Next, we prove sufficiency. Suppose there exist Borel sets B, C S C B* such that p ( B * ) = p * ( S ) = p ( B * ) . We know that S will be measurable provided that P*(S) + P*(S") = P ( X ) . Since p* is subadditive, it suffices to prove that p* (S) p * ( S c ) < p ( X ) . We know that p ( B * )+ PL(B:) = P ( X ) = P ( B * )+ P ( ( B * ) " ) ,

+

+

so that p((B,)") = p ( ( B * ) ' ) .By the monotonicity of ,LL* we see that p * ( S ) = p ( B * ) and p * ( S c ) < p ( ( B * ) ' ) .

Thus

Corollary 3.2.1 Let p be a a-finite, countably additive measure, constructed from some finitely additive measure on a field in U C p ( X ) , using the Hopf Extension 23The term p-measurable would be used if there were any ambiguity regarding the measure under consideration.

MEASURABLE SETS, BOREL SETS, AND THE REAL LINE

35

Theorem (2.4.1). Then a set S in p ( X ) is measurable ifand only ifthere exist Borel sets B* and B* in B(U)such that

B, G S

C

B* and p(B*\B,)

= 0.

Proof: Apply o-finiteness, taking note of the fact that the union of countably many w sets of p-measure zero will have p-measure zero. The reader should note that if S is a measurable set, then p * (S) = p( S ) . That is, if S E 2,then there exist B*and B, E IB c 2 such that P(B*) =

4 s )= PL(B*).

This is the first result of several that will help us to explore the nature of Lebesgue measurable sets. The exercises below provide very important additional insights that will be useful frequently.

Definition 3.2.1 A set B c IR is called an F,-set if and only if it can be expressed as the union of countably many closed sets. A set B c IR is called a Gs-set if and only if it can be expressed as the intersection of countably many open sets. 24 In view of Exercise 3.2 below, F,-sets and G,j-sets are special types of Borel sets in the real line.

EXERCISES

3.2 Prove that every open set G E [ - N . N) is a Borel set and that every closed set F c [-N. N) is a Borel set. In particular, each singleton set { p } is a Borel set, and each interval is a Borel set. (Hint: You may use the fact from advanced calculus that every open subset of JR is the union of countably many open intervals.) 3.3 Suppose that S E [- N, N) . Use Theorem 3.2.1 to prove that Sis a measurable subset of [ - N , N ) if and only if for each E > 0 there exist an open set G 2 S and a closed set F 5 S such that p ( G ) - p ( F ) < E . (Hint: The measure of a Borel set is the same as its outer measure. To produce G , think about expanding the half-closed, half-open intervals very slightly to make them open.) 3.4

Prove that in Theorem 3.2.1 we can take the set B , to be an F,-set and the set

B* to be a Ga-set. (Hint: Use Exercise 3.3.) Remark 3.2.1 The measure p* on the power set of X N = [-N. N ) that we have defined in this section is called Lebesgue outer measure and is denoted also as 1 *. We define the Lebesgue inner measure by the formula 1*(S) = q X N ) - l*(SC). 24These notations are universal in the mathematical literature. The name 4 comes from the German word gebier, meaning a domain. which is normally open. and from the Greek 6, analogous to the Roman d, for the German word durchschnitt, meaning intersection. The name Fo comes from the French word fermP, meaning closed, and the Greek letter u, analogous to the Roman s. for sum.

36

LEBESGUE MEASURE

It follows from Theorem 2.4.2 that S G X , y is Lebesgue measurable if and only if l * ( S )= l * ( S ) ,in which case I ( S ) = l * ( S )= l * ( S ) .

Definition 3.2.2 We will call the measure 1 defined in Remark 3.2.1 Lebesgue measure on XN = [-N. N). The Lebesgiie measurable sets in Xn: are the sets in the family C(X,) = ( A E y ( X )1 l * ( W )= l * ( U 7 n A ) +l*(T.I' n A') V U 7 E (53(X)}.

3.2.1 Lebesgue Measure on IR Next, we extend the definitions of Borel sets, measurable sets, and Lebesgue measure to IR from XN = [-N.N). We will apply Corollary 2.4.1 so as to make use of the a-finiteness of IR with respect to Lebesgue measure. One may replace the decomposition IR = UNEN X N by

where SN = X N \ X N - ~ is a sequence of mutually disjoint Borel sets of finite Lebesgue measure.

Definition 3.2.3 We say that A E %(IR), the family of all Borel sets in the real line, if and only if A n S N E % ( S N )for each N E IN. Call A E C(IR), the family of all measurable sets in the real line, if and only if A n S N E ~ ( S Nfor ) each N E IN. Finally, define the Lebesgue measure of A E C(IR) by

[ ( A )=

l ( An S N ) . NEE

Theorem 3.2.2 Let 0 denote the set of all open subsets of IR.Then the fatnil?' 23 of all Borel sets in the line is generated by 0:

23(IR)

=

IB(0).

Proof: The reader will provide a proof in Exercise 3.5.

Remark 3.2.2 We began the study of Borel sets and of measurable sets in the real line by considering intervals of the form [ab ) , because we need Lebesgue measure to generalize the concept of the length of an interval. The use of left-closed, half-open intervals was a convenience for describing a j e l d of sets so that we could use the theorem that the monotone class and Borel field generated by the elementary sets would be the same. At this point, it is advantageous to think of the 0-field of Borel sets in the real line as being generated by its topology-that is, by the family of open sets. First, this

MEASURABLE SETS, BOREL SETS, AND THE REAL LINE

37

establishes that the family of Bore1 sets is canonical, meaning that it is independent of the choice of decomposition of IR into the union of countably many elementary sets of finite measure. Moreover, this interpretation generalizes to topological spaces that are different from IR. EXERCISES

3.5

Prove each of the following statements about sets A c IR. Let EN be the field of elementary sets in Slav = XN\XN-I and denote

E(IR)

=

1

E

N

=

U En El, E E n V n 6 N.V N 11=1

~

E

IN

1

.

Prove that Q(R)is the a-field generated by the field E(R). (Hint: Use Corollary 2.4.1 .) Prove Theorem 3.2.2: Show that %(IR) is the a-field generated by the family of all open sets in IR,or equivalently, generated by the family of all closed sets. Prove that A E 2(R) if and only if there exist B * and B, in Q(R)such that B, E A E B* and 1(B*\B,) = 0.Explain why it would be insufficient on IR to know only that p ( B * ) = p ( A ) = p ( B * ) . Show that 1 is a countably additive measure on both %(R) and 2(IR).(Hint: You may use theorems from advanced calculus concerning absolutely convergent double series.)

3.6

Let E be any measurable subset of IR. Define the set

E +c

= {e+c

I e E E}.

We will prove the translation invariance of Lebesgue measure. Suppose first that E is an open set, and prove that I ( E ) = I(E + c). (Hint: You may use the fact that every open subset of the real line is the union of countably many disjoint open intervals.) Prove that translation preserves the family of G6-sets, the family of F,-sets, and the family of Lebesgue null sets. Prove that E is measurable if and only if E c is measurable. Prove that 1(E) = I(E c) for each Lebesgue measurable set E . Translations modulo 1: Now let T , : [O. 1) -+ [0, 1) by

+

T,(Z) = n:

+

+ c - .1 + cj.

where thefloorfunction 1x1 denotes the greatest integer that does not exceed 2 . Prove that T , preserves both the measurability and the measure of each measurable subset of [0,1).(Hint: T , is the identity map if ?z E Z.Partition E into two suitable subsets.)

38

3.7

LEBESGUE MEASURE

Let S = (IR\$) n [O. 11, and let 1 denote Lebesgue measure. a) Show that 1(S) = 1. b) Let E > 0. Construct a closed subset F c S such I ( F ) > 1 - E . c) Explain why it is impossible for F to contain any interval of length greater than zero.

3.8 Let S E 2 be a Lebesgue measurable subset of JR. Suppose that for each finite interval I G IR we have I (S n I ) < 1 ( I ) . Prove that 1 ( S ) = 0. 3.9 Let E E c(R) be any Lebesgue measurable subset of the real line for which l ( E ) < a. Let f(r) = l ( E n (-co.z). a) Prove that f E C(IR), the vector space of continuous real-valued functions on the real line. b) Let cy E (0. 1). Prove that there exists a measurable set E , c E such that 1(E,) = crl(E). 3.3 MEASURE SPACES AND COMPLETIONS

Definition 3.3.1 A measure space is any triplet (X,Q. p ) where X is a set, U is a a-field of subsets of X, and p is a countably additive measure on U. In a measure space, a set A E Q is called a null set provided that p ( A ) = 0. A measure space is called complete provided that every subset of a null set belongs to U. A pair (X. Q) is called a measurable space provided that 2l is a a-field in p ( X ) . EXERCISE 3.10 Let X = IR,the real line, and Q = Q(IR),the a-algebra of all subsets of X. Define v ( E ) = # ( E n Z), the number of integers in E . a) Prove that v is a countably additive measure on Q. b) Let f(r) = v([O.r ) ) .Is f continuous? Justify your answer. c) Is (X. Q. v ) complete? Justify your answer. If A is a null set and if B E Q is a subset of A , then the monotonicity of ,LL implies that p ( B ) = 0, so that B is a null set. The reason that not every measure space is complete is that a subset of a null set may fail to belong to U. However, we do have the following corollary of the Hopf Extension Theorem.

Corollary 3.3.1 Let (X.Q * . p * ) be any measure space produced by applying the Hopf Extension Theorem (Theorem 2.4.1) to produce a Carathbodory outer measure p*, where%* is the a-jieldof all p*-measurable sets. Then (X.U*,p * ) is a complete measure space. In particulal; each of the Lebesgue measure spaces ([-N, N ) . C[-.U. N). l ) is complete, as is

(IR,2(JR).1).

MEASURE SPACES AND COMPLETIONS

39

Proof: We will not suppose that p* ( X ) < ix, since this is not needed. Suppose that A E U* is a null set, and let B c A. We need to prove that B is measurable. Thus we need to show that for each W E Q ( X )we have

p*(Nr)= p*(W n B)+ p * ( i t ' n B'). Since A is measurable. we know that p * ( W ' ) = p*(M' n A )

+ p*(It?n A').

and

0 6 p * ( W n B)6 p*(I1.' n A ) 6 p * ( A ) = 0. Hence p*(W n B) = p* (IY n A ) = 0. It follows that

p * ( I Y )= p * ( W n A') 6 p*(T/t' n BC)6 p*(Tt-) by monotonicity. Thus

p*(N') = p*(W

+

n A') = p * ( W n B') = p * ( H Tn B) p * ( W n BC).

Hence B E U*. The real cases ( [ - N , N ) ,C [ - N , N ) ,I ) are covered directly by the preceding general argument. And the case of (IR. C(IR). 1 ) is covered by the completeness of 1 on [ - N . N ) for each N E IN, since Lebesgue measure on the real line is 0-finite. It will follow from Exercise 3.1 1 that the family of Lebesgue measurable subsets of [O. 1) has cardinality 2' which is strictly greater than c = 2 N n ,the cardinality of the set IR. of all real numbers. The exercise asks us to construct a Borel set that is known as the middle thirds Cantor set, C.

EXERCISE 3.11 Let C1 be the set [O: 1]\ of length i.Let c 2 =

(i?i),a union of two disjoint closed intervals, each

((is ;) (i.;))

c,\

u

.

so that again we discard the middle thirds, leaving four disjoint closed intervals, each of length We proceed inductively in this manner. each time discarding middle thirds, producing a descending chain of nested sets C1 2 Cz 2 C, 2 . . .. Define the Cantor set

i.

L

C= n c . n=1

a) Prove that C is a Borel set with measure zero. b) Use ternary expansions of the real numbers to produce a bijection between the elements of C and the set of all infinite sequences of 0s and 2s. Explain

40

LEBESGUE MEASURE

why this set is uncountable and has the cardinality c of the continuum of real numbers. c) Prove that C is a closed, nowhere dense subset of the unit interval [O. 11.

Remark 3.3.1 We sketch here a proof that the Borel measure space ( X N . 13.P ) ?

consisting of all the Borel sets in the interval X N = [-N. N ) , is nor complete.25 The argument will not be self-contained, since it will depend upon outside knowledge of transfinite induction and how that process can be used to construct the a-algebra 13. What we will do is to show that there are not enough Borel sets to account for all the subsets of the middle thirds Cantor set. We will explain why the cardinality of the set !I3 of all Borel sets in X>Vhas the cardinality c

=

2"l < 2" = #rp(C).

where C is the middle thirds Cantor set. The interested reader can consult [8] for the details of the following construction by transfinite induction of 93. For each set S c p ( X ) ,denote by S * the set of all unions of countably many members of S and all differences of elements of S. Let k = # S , the (generally infinite) cardinality of S. Sequences in S correspond to functions f : IN --* S, and the cardinality of the set of these is the (infinite) cardinal number k N o .Suppose for the moment that k = c = 2 No. Then

3x

I = max(3.7)

Thus the cardinality

#S*

=

c = #S.

First, let C c ? ( X ) be the field of elementary sets. It is easy to see that the cardinality of C is c. Let CO = C,and for each finite or transfinite ordinal number N let

25A different proof, based on the Cantor function, of the existence of measurable sets that are not Borel sets IS given in Exercise 7.13.c. 26The smallest infinite cardinal number is the cardinality of the set IN of natural numbers and it is written as No (read aleph-null). The next two symbols we have used are bet 1and gimell. which are the next two letters of the Hebrew alphabet, or aleph-bet. Each infinite cardinal number is an equivalence class of infinite sets. Each infinite ordinal number is an order-preserving equivalence class of well-ordered sets.

MEASURE SPACES AND COMPLETIONS

41

Let R denote the first uncountable ordinal number. It can be shown that

WE) =

u

Ea

a 0.

In the former case, countable additivity of Lebesgue measure would imply that 1 ( X ) = 0, which is impossible since I ( X ) = 1. But if /(*If) > 0, it would follow that 1 ( X ) = m, which is impossible as well. Hence $ 2.

EXERCISE

3.12 Let S be any nonmeasurable subset of IR. Prove that the outer measure I*(S)> 0. "A more general result is presented soon as Theorem 3.4.4. the proof of which utilizes Steinhaus's theorem from Exercise 3.21. A further development of the construction of a nonmeasurable set appears in the Appendix as Example A. 1.

SEMIMETRIC SPACE OF MEASURABLE SETS

43

3.4 SEMIMETRIC SPACE OF MEASURABLE SETS

Definition 3.4.1 A set S equipped with a function d : S x S + [O. E) is called a tnetric space ( S ,d ) , with metric d , provided that d has the following properties: i. d(a. b ) = d ( b , a ) for all a and b in S. ii. d(a. b) = 0 if and only if a iii. d ( a . c)

=

b.

< d ( a , b ) + d ( b . c) for all a, b, and c in S.

Property (iii) is called the triangle inequality. If the pair (5'. d ) lacks the only if part of property (ii) but has the others, then it is called a semimetric space. In any metric or semimetric space, a sequence a , is called a Cauchy sequence if and only if for each E > 0 there exists N E K such that rz and m greater than or equal to implies that d(a,. a,) < E . A metric or semimetric space is called complete if and only if for each Cauchy sequence a, in S there exists a E S such that a,? + a in the sense that d(a,, a ) -, 0 as n + E."

Theorem 3.4.1 Let ( X .U,1-1) be any finite measure space. For each pair of sets A and B in U, define the symmetric difference A A B = ( Au B)\(A n B ) and define d(A.B ) = p ( A A B ) . Then the pair (U. d ) is a complete semimetric space. The reader should note that this concept of completeness as a metric space does not have the same meaning as completeness of a measure space in the previous sense, in which every subset of a null set is a null set. The present theorem does not require the measure space to be complete in the sense of Theorem 3.3.1. Proof: To prove that d is a semimetric, everything except the triangle inequality is obvious. To establish the triangle inequality, it would suffice to prove what we will call the triangle inequa1it;vfor sets:

AAC

c ( A B)u (Ba C )

(3.1)

To prove this containment, we note first that if x E A C, then either .c E '4 or E C, but not both. Thus A A C = (A\C) u (C\A). Hence if .T E A A C. it follows that either

x

x E A\C. and thus or else

x

E

C\A, and thus

1 1

x

E

x @

B , and s E B A C. or B,and J E A a B.

x E B, and

x$

.1:

E

A

B,and ,T E B A

B.or

c.

28However, for limits to be unique, we need the space to be a full-fledged metric space.

44

LEBESGUE MEASURE

In order to prove that the semimetric space is complete, we take a Cauchy sequence {ATL 1 A, E U Vn E IN}. That is, for each E > 0 there exists N E IN such that n and m 2 N implies that d(A,. A,,) < E. We need to prove that there exists A E U such that d(A,. A) -+ 0 as n 4 cc. For each k E K there exists nk E N such that n and m 2 711, implies that

Moreover, we can select the sequence n k so that n k < nk+l for all k . We will define the limit superior of the sequence of sets A,, by r

A

=

limsup~,, k+

r

UA

=

~ ~ .

p=l k=p

1

the set of all elements that are present in infinitely many of the sets A,, . Observe that A E U because U is a a-field. We will prove that d(A,, A) 0 as n CC. Denote -+

Cp =

-+

U A,,,and D, = n A n k . f

f

k=p

b=p

Observe that C, is a descending sequence of sets with intersection equal to A. On the other hand, D , is an ascending sequence of sets with union denoted as

u" n Y.

liminf A,,

=

A,,

p=l k=p

The limit inferior of the sequence of sets A,, is therefore the set of all elements that are present in all but finitely many of the sets A,, . Observe that

D, C A,, S C,, and D, C A C C,,

" 1

1

a 3 = 2 p -4' 0 k=p

SEMIMETRIC SPACE OF MEASURABLE SETS

45

as p -+ a.The inequality (i) is justified by the fact that in order for an element 1' to be in the union of the pth tail of the sequence of sets but not in its intersection, there must be at least one of the sets A,, in the union that contains 2 and another set ATI3 that does not contain 5 . Iterated application of Equation (3.1) using in place of the set B each of the sets indexed between n k and n3 shows that there must be at least one value of k such that this element lies in il,, A A,,,, . In fact, suppose for specificity that n3 < n k . Then

Thus

as p

-+

co. Hence if n > 1zp we have 1

< -2 P+ -

1 2P-1

4 0

a s p -+ 00.

Remark 3.4.1 We could replace the semimetric space of measurable sets in Theorem 3.4.1 by a metric space in which the points of the space are equivalence classes. Define A B if and only if p ( A A B ) = 0. That is, two sets A and B are equivalent if and only if the measure of their symmetric difference is zero. We form the quotient space U/V where V denotes the family of null sets in 'u. And if A and B are equivalence classes, we define the full-fledged metric d ( A ,B ) = d(A, B ) . The reader should verify that the value of the metric is independent of which representatives are selected from each of the two equivalence classes.

-

In the next theorem, we apply what we have learned about the metric on the space of measurable sets to Lebesgue measure on X N = [-AT, AT).

Theorem 3.4.2 In the semimetric space (U.d ) obtained from the Bore1 measure space ([-A7% N ) , ' u . 1 ) by letting d(A.B)= 1(A A B),thej?eld Eofelementat-ysets is a dense subset of U. That is, i f B E U, tlieri there exists a sequence of elementar?. B in the sense that d(B.E n ) -+ 0 as n -+ E. sets En E C such that E , -+

The proof is Exercise 3.13

46

LEBESGUE MEASURE

EXERCISES

3.13 Prove Theorem 3.4.2. (Hint: Use the definition of CarathCodory outer measure to show that there exists a suitable sequence of elementary sets.) 3.14 In the semimetric space ( 2 , d ) formed from ( [ - N . N ) , 2 , 1 ) ,where 1 is Lebesgue measure, prove that each of the following sets is dense: a) 0,the set of all open sets in [ - N . N ) . b) K, the set of all closed sets in [-Ar. AV). 3.15 Let ( X ,U. p ) be any finite measure space arising from the Hopf Extension Theorem applied to a finitely additive measure on some field E. a) Prove that Theorem 3.4.2 is true for ( X .U. p ) . b) Explain why we need the measure p ( X ) < so in part (a). The following concept is purely topological and is not part of measure theory, although it can be applied to metric spaces that arise from measure theory as explained above.

Definition 3.4.2 If (X, d ) is any metric space, a subset S E X is said to be a set of theJirst category if and only if S can be written as the union of countably many nowhere dense sets.29 A subset S E X is said to be of the second categoiy if and only if it is not of the first category. For example, the set Q is a set of the first category in Euclidean topology, since

IR,equipped with its usual

a countable union of singleton sets. And each singleton is clearly closed and nowhere dense.

Theorem 3.4.3 (Baire Category Theorem) A complete metric space is a set of the second category The proof is given in Exercise 3.16. In the Baire Category theorem the concepts of being closed, dense. or nowhere dense are understood in terms of the given metric. The reader can apply the Baire Category theorem to the complete metric space U/n of equivalence classes of Lebesgue measurable sets of the measure space ( [ - N . N ) .2.1) in order to prove that measurable sets with a certain bizarre property are ubiquitous. See Exercise 3.17. The Baire Category theorem has many other interesting consequences, some of which are treated in the exercises below. "Nowhere dense means that the closure 5 of S contains no open set other than the empty set

SEMIMETRIC SPACE OF MEASURABLE SETS

47

EXERCISES

3.16

Prove the Baire Category theorem (3.4.3). Here is a suggested outline.

a) Show that it suffices to prove that in a complete metric space the intersection of countably many open, dense sets must be nonempty. b) Let 0, be a sequence of open, dense subsets of the metric space (X,p ) . Prove that there exists a decreasing nest of closed balls

with r,

-+

0.

c) Use completeness to prove that

n:=:=, ok z 0.

3.17 Call the Lebesgue measurable set S c [-N. N) a ghost set if and only if S has the property that for every i n t e n d I C [-N. N) we have

o < I(S n I ) < I(I).30 a) Show that the family 6 of ghost sets in the unit interval is a set of the second category. b) Determine whether 6 is closed under i. unions of two elements. ii. complementation of an element. iii. intersection of two elements. c) Let G be a ghost set in [ - 1.1)and prove that 1G is rtot Riemann integrable on [-1,1]. (This exercise shows that in the sense of Baire category, most indicator functions of measurable sets in a finite interval are not Riemann integrable. However, the reader will see that they are all Lebesgue integrable.)

3.18

a) Use the Baire Category theorem3' to prove that the set (IR\$) n [a,b] is not an F, set if a < b. b) Show that the set Q n [a.b] is not a G s set if a < b. (Hint: If Q and Qc were both Gpsets, then the empty set would be the intersection of countably many dense open sets, which would violate the Baire Category theorem.) c) Give an example of a subset S of the real line that is a Bore1 set but is neither an F, nor a Gg set. 3.19

Let S be the set of points

2

at which a function f : IR

-+

IR is discontinuous.

30The behavior of ghost sets makes an interesting contrast with Exercise 3.8. "In this problem, think of [a, b] as being a complete metric space with respect to ordinary Euclidean distance on the real line.

48

LEBESGUE MEASURE

a) Prove that S must be an F,-set. (Hint: It may be helpful to consider the concept of the oscillation o f ( p ) = l i n i s u p f ( x ) - liniinf f ( x ) , X+P

X-+P

as defined in advanced calculus.3’ You may use the fact that a function f is continuous at p if and only if o f ( p ) = 0.) b) Prove that it is impossible for the set S to be precisely the set $‘ of all irrational numbers. (Use the result of Exercise 3.18.a.) c) Give an example of a bounded monotone function f for which the set S of all points of discontinuity is precisely Q.33

3.20 Equip the space C(IR) of all continuous functions on the real line with the standard sup-norm: l l f ~ ~ s u p = sup{ I f ( . ) ] I z E R}.Prove that for each 17 E IN the set

is an open, dense subset of C(R). Apply the Baire Category Theorem to prove that the set of nowhere differentiable continuous functions is a set of the second category in C(R).34(Hint: Think in terms of sawtooth functions.)

3.21 Prove the following theorem of Steinhaus. Suppose A c measurable and suppose its Lebesgue measure l(’4) > 0. Denote

A -A

= {X - y 12 E

A. y

E

IR is Lebesgue

A}

Prove that A - A contains an open interval around 0. Explain why it would suffice to give a proof if 0 < l ( A )< m. Let

f(x) = L((x

+ A) n A).

It may help to use the following procedure. 35 a) Show that if f(z)> 0, then x E A - A. b) Show that Steinhaus’s theorem follows i f f is continuous at 0. c) Show that

IL(A)- L(B)I < l ( A A B)= d (A ,B ) if A and B are measurable sets of finite measure and if d is the semimetric for the space of measurable sets. ”See for example the book [20]. 33See,for example, Exercise 7.10 in [20]. 3JThis problem is not about measure and integration. We include it here because of its general interest as a corollary to the Baire Category Theorem. 35An alternative proof of Steinhaus’s theorem is given in Exercise 6.10.

SEMIMETRIC SPACE OF MEASURABLE SETS

49

d) Show that f is continuous at each point z if A is a finite interval. Then prove the same thing if A is an elementary set. (It will be easier to give a proof for these two special cases.) e ) Use the triangle inequality for d, together with the result of part (d), to show that f is continuous at each .c E IR,assuming only that A E C with finite measure. With the help of Exercise 3.21 we can prove a generalization of Example 3.1. We will show that every subset P E R of strictly positive measure must contain a nonmeasurable set.

Theorem 3.4.4 r f P subset of P.

E

C(R)and i f l ( P ) > 0, then there exists CI noizmeasurable

Proof: Let Q denote the set of all rational numbers, as usual. We will define again an equivalence relation on IR by

X-YUX-YEQ By the Axiom of Choice, we can find a cross section r We can express the real line as a disjoint union

36

of the quotient space IR/ -.

-

since if -) + y = y’+ q’, then 3 - y’E Q. This would make 3 A,’ and thus 3 = -,’, since r is a cross section of IR/ -. If P n (r + q ) were not Lebesgue measurable for some q E Q, then we would be finished because P would have a nonmeasurable subset. However. if

P n (r + 4 ) = Pq E C(R) for each q

E

Q, then we observe that pq - pq E

(r + q ) - (r + q ) = r - r.

where I‘- r is disjoint from the dense set Q\{ 0) for the reasons explained just above. Thus the difference Pq - Pq of a supposedly Lebesgue measurable set with itself fails to include any open interval around 0. By Steinhaus’s theorem (Exercise 3.21), Pq must have measure zero. Hence P itself is the union of countably many disjoint null sets, which contradicts the hypothesis that 1(P)> 0. More information about the nonmeasurable subsets of P can be found in [lo].

EXERCISE 3.22 Prove that the cardinality of the family of all nonmeasurable subsets of IR is the same as the cardinality of the family of all measurable sets: 22”0. (Hint: If P is a nonmeasurable set and S is any disjoint measurable set, what can you conclude about S u P?) 36That is. r contains exactly one element of each equivalence class in R

50

LEBESGUE MEASURE

3.5 LEBESGUE MEASURE ir.1 I R ~ By the 2N-cube in IR" we mean QN

=

[-N,N)"

=

[-N.Ar) x . . . x [-N,?V).

a Cartesian product with n factors, each being a copy of the interval [-N. N ) . We will denote a typical rectangular block in Q ,v by R = J ~ .x. . x J , .

a Cartesian product of n intervals of the form J ,

= [a,, b t ) . We

define the measure

n z= 1

the product of the lengths of the n intervals. By an elementap set E E e we will mean the union of finitely many rectangular blocks as defined above, and I is a finitely additive measure on e.

Theorem 3.5.1 The family ~ ( Q N of) elementan sets is a field of sets contained in ? !3 ( [ - N . N ) " ) . There is a countably additive measure 1 dejined on the generated Boreljield '23 = IB ( ~ ( Q N ) that ) coincides with the measure I on ~ ( Q N ) where , 1 of a rectangular block is its Euclidean volume. The extension of 1 from 2 ' to 93 proceeds as it did in Theorem 3.1.1 for the one-dimensional case, using the Hopf Extension Theorem. The proof is virtually identical, since the main tool is the finite intersection property for compact sets. That principle, presented in Exercise 3.1, is valid for IR" as well. We leave it to the reader to check this fact. Next we extend the definitions of Borel sets, measurable sets, and Lebesgue measure to IR" from Q N = [ - N . N ) " . We will make use of the a-finiteness of Euclidean space, just as we did for the line in Definition 3.2.3. One may express

where SN = QN\Q,~-I for each iVE N . Thus the mutually disjoint elementary sets S N all have finite Lebesgue measure.

Definition 3.5.1 We say that A E B(lR"),the family of all Borel sets in R7*, if and ) each N E IN. Call A E C(IRn), the family of all only if A n S N E ' 2 3 ( S ~for measurable sets in IR",if and only if A n S N E C ( S N )for each N E IN. Finally, define the Lebesgue measure of A E C(IRn) by

1(A)=

C 1(A NEW

nSN).

LEBESGUE MEASURE IN

Theorem 3.5.2 Let 0 denote the set cf all open subsets of all Borel sets in IR" is generated by 0:

of

a''

51

IRn. Then the family '23

Proof: This proof is left to the reader in Exercise 3.23.

Remark 3.5.1 There are advantages to thinking of the a-field of Borel sets in Euclidean space as being generated by its topology-that is, by the family of open sets. This is a viewpoint that generalizes in interesting ways-for example, to topological groups. We began the study of Borel sets and of measurable sets in the real line by considering half-closed, half-open rectangular blocks, because we require Lebesgue measure to generalize the concept of the volume of a box. The use of half-closed, half-open blocks was primarily a convenience for describing a field of sets, so that we could use the theorem that the monotone class and Borel field generated by the elementary sets would be the same.

EXERCISES

3.23

Prove each of the following statements about sets A E IR If : a) Prove that B(IRn)is the a-field generated by

b) Prove that A E C(IR") if and only if there exist B* and B, E B(JR")such that B, s A E B* and 1(B*\B,) = 0. c) Prove that 1 is a countably additive measure on B(IR"). d) Prove that the open sets and the closed sets are Borel sets in R n . e) Prove Theorem 3.5.2: B(IR?L) is the a-field generated by the family of open sets or, equivalently, by the family of closed sets in IR" .

3.24

Suppose E is Lebesgue measurable in IR", and define

E+c={e+cIeEE}. the translate of E by c. (Addition refers to vector addition in this context.) We will prove the translation invariance of Lebesgue measure. a) Prove that E is a null set if and only if E c is a null set. b) Prove that E c is Lebesgue measurable. c) Suppose that E is an elementar?;set in IR",and prove that I ( E + c) = 1 ( E ) . d) Let E be any measurable set, and prove that 1 ( E c) = 1( E ) .

+

+

+

3.25 Suppose E is a subset of IR" and let -E = {-e 1 e E E } . We will prove the invariance of Lebesgue measure under rejection through the origin. a) Suppose first that E is an elementary set in IR". and prove that -E is a Borel set and / ( - E ) = 1(E).

52

LEBESGUE MEASURE

b) Finally, let E be a measurable set, and prove that 2( - E )

= I(E).

3.26 Suppose A and B are measurable subsets of IR",each one of strictly positive butfinitemeasure. ProvethatthereexistsavectorcE IR"suchthatl((A+c)nB) > 0. (Hint: Consider the outer measure of A and B.) 3.27 Let E > 0. Construct an open, dense subset S of IR" for which the Lebesgue measure 1 ( S ) < E . 3.6 JORDAN MEASURE IN IRN Lebesgue measure will be the foundation for defining the Lebesgue integral and for proving its properties. Jordan measure is the corresponding foundation for the Riemann integral, though Jordan measure (also called Jordan contenf)is often not taught explicitly in advanced calculus courses. Although not required for understanding the Lebesgue integral itself, the study of Jordan measure will help us to understand the relationship between the Lebesgue integral and the Riemann integral, which the Lebesgue integral supersedes. Moreover, Jordan measure will enable us to prove Lebesgue's theorem (6.3.11, classifying all Riemann integrable functions in terms of the Lebesgue measure of the set of points of discontinuity.

Definition 3.6.1 Let E be the collection of unions of finitely many closed blocks in the closed cube QN, where N E IN is fixed arbitrarily. Define the outer Jordan ) measure for each A E ~ ( Q Nby v*(A) = inf{l(E) 1 A C E , E

E

E}

E

E}.

and let the inner Jordan measure be defined by v,(A) = sup{l(E) I A 3 E . E

Here 1(E) denotes the volume, or Lebesgue measure, of the union of finitely many rectangular blocks that comprise E. We define the set 3 to be the family of all Jordan measurable sets, where A is Jordan measurable if and only if %)*(A)= u*(.4), in which case either number is called u(A), the Jordan measure of A. We will see that the weakness of Jordan measure stems from the need to cover a set using only unions o f j n i t e l y many rectangular blocks. This has the unfortunate effect that Jordan measure is only finitely additive, and that is insufficient for the needs of analysis.

EXERCISES 3.28

Prove that Jordan measure is nor countably additive.

3.29 Use Definition 3.2.1 and DeMorgan's Laws to prove the following properties of inner and outer Jordan measure, in relation to inner and outer Lebesgue measure, for all A E ~ ( Q N ) The . sets Ei are in E .

53

JORDAN MEASURE IN IRN

b) u*(A)6 1,(A) .$ l*(A)6 .*(A). It follows that every Jordan measurable set is Lebesgue measurable and that its Lebesgue measure equals its Jordan measure. We will see that not every Lebesgue measurable set is Jordan measurable, however. Thus Lebesgue measure is an extension of Jordan measure.

Theorem 3.6.1 The family 3 of all Jordan measurable sets in X and v is aJinitely additive measure on 3.

= Q,v

is a field,

Proof: Let A and B lie in 3. Since

u ( X ) - u* (X\A) = u,(A) and w(X)- t i *

(X\A)

=

u*(A).

it follows that X\A E 3. Both A u B and A n B are in 3 since the union and intersection of any two elementary sets is again an elementary set. And u is finitely additive on 3 since on that field of sets v agrees with 1. N

EXERCISE

3.30 A subset A of X = QN is Jordan measurable if and only if for each there exist in & sets El C A E Ez such that v(Ez\El) < E . Definition 3.6.2 A set N c X and v(N) = 0.

=

E

Q N is called a Jordan null set if and only if N

Theorem 3.6.2 A Lebesgue null set F c X

=

>0 E

3

Q.v that is closed is also a Jordan

null set.

Proof: It suffices to prove that F E 3. It is easy to see that if E > 0, there exists a set G that is open in IR" and such that F c G and I(G) < e. But the set G is a countable union of open rectangular blocks. Since F is compact, the Heine-Bore1 theorem implies that F can be covered with finitely many of these open rectangular blocks with measure no greater than that of G. Thus there exists an E 2 F such that E E &, and v ( E ) = 1(E)< E . Thus F is a Jordan null set since $3 F c E .

Theorem 3.6.3 I f A C X

=

O N ,then A E 3 ifand only ifthe boundary dA = iT\A",

the difference between the closure and the interior of A, is a Jordan null set. Proof: Suppose first that A E 3. Since the boundary 8A is a closed set, it will suffice to show that it is a Lebesgue null set, since that will imply that it is also a Jordan null set. We know that for each k E IN there exist sets Ek C A C F k such that both Ek and Fk are in & and 1 (Fk\Ek)

=

1

1 (Fk\E,O) < k

54

LEBESGUE MEASURE

Let

F

=

n PI,

and E =

kEN

U E;. I,&

It follows that dA E F\E, and 1 (F\E) = 0. Thus dA is a Lebesgue null set and also a Jordan null set. Now we suppose that dA is a Jordan null set. For each E > 0, there exists E E E such that E" 2 dA, with l ( E ) < E . We seek to prove that A E 3.Denote X = Q-' and ' h

E"

=

X\E"

=

U BI,E . E

1=1

Suppose that one of the rectangular blocks BI, contained a point p E '4 and also a point q E A". Then it would follow that the straight line segment from p to q must contain a boundary point of A, which contradicts the hypothesis that dA E E . (See Exercise 3.32.) Now let El be the union of the blocks B k that lie inside il,and let Ez be the union of the blocks that lie outside A. Then the elementary set G\E," = E , and this means that El E A E % and 1 (%\El) < E . Thus A E 3.

EXERCISES

3.31 Let A = Q n [O, 11,the set of all rational numbers in [0, 1 ) . Prove that 8A is neither a Lebesgue null set nor a Jordan null set, so A $ ,I. On the other hand, show that A E !B, the family of Bore1 sets. 3.32 In IRn, show that if a rectangular block B contains both a point of the set E and a point of the complementary set E" = IRn\E, then B contains a point in JE, the boundary of E.

MEASURABLE FUNCTlONS

If X is a set and U c p ( X ) is a 0-field, then ( X ,U) is called a measurable space. If p is a countably additive measure defined on U, then ( X ,U.p ) is called a measure space. In this chapter we will introduce the family of measurable functions for which we will seek to define the Lebesgue integral. We will prove the very important fact that pointwise limits of measurable functions must be measurable. This is encouraging because pointwise limits of Riemann integrable functions need not be Riemann integrable.” 4.1 MEASURABLE FUNCTIONS Definition 4.1.1 Let ( X .2.p ) be a measure space. i. I f f : X

-+

IR,we say that f

is U-measurable provided that

j-l(-CO,u)

=

{x E X

1 f(x) < a } E U

37See Example 1.3. Measure and Integration: A Concise Introduction to Real Anulysis. By Leonard F. Richardson Copyright @ 2009 John Wiley & Sons, Inc.

55

56

MEASURABLE FUNCTIONS

for all a E R . ~ * ii. If f : X -+ C , the complex numbers, we write f(2) = u(,r) + i ~ ~ ( 3 for ') real-valued functions u = 82f and 2' = Sf. We say that f is 2-measumble provided that both u and 2' are %-measurable. iii. I f f : X -, S, where S is a topological space, we say that f is %-measurable provided that f - l ( G ) E % for every open set G s S. The reader may note correctly that the concepts of measurability presented above have a formal similarity to the definition of continuity. A function between topological spaces is called continuous provided that the inverse image of each open set is open. Of course, for measurability, the inverse image of an open set must be measurable, and measurability is by no means synonymous with being open. In IR ', every open set is Lebesgue measurable, but the converse is clearly false. The following exercises establish the equivalence of the three different forms of the definition of measurability for functions that are presented in Definition 4.1.1.

EXERCISES

4.1 Let ( X ,U. p ) be a measure space. Use the steps below to show that the concepts of measurability in Definition 4. I . 1 for both real and complex-valued functions are consistent with the concept of measurability for a topological space valued function. a) Show that if f : X --+ IR is %-measurable, then f (G) E U for every open set G E IR. b) Show that f : X -, IR satisfies the definition of measurability if and only if f-'(G) is measurable for each open set G E IR. Do the same for complex-valued functions f .

-'

4.2 Let ( X .%, p ) be a measure space. Let f : X -+ IRn, the latter space being equipped with its usual Euclidean topology and the Borel field generated by the open sets. a) Show that the family

(5 = { A E

p(IR")1 f - l ( A )

E %}

is a a-field. b) Prove that f is measurable if and only if f-'(B)

E %

for each Borel set

B.39 4.1 .I Baire Functions of Measurable Functions It will be important to know that many combinations of measurable functions and many functions of measurable functions are again measurable. To investigate this, we need the following definition. '*This definition is motivated by Section 1.3. "For information about .f-l of a measurable set, see Exercise 7.14.

MEASURABLE FUNCTIONS

57

Definition 4.1.2 Let (X. %, p) be any measure space arising from the Hopf Extension Theorem, applied to some measure on afield E. If f : X S, where S is a topological space, we say that f is a Baire function provided that -+

f-'(G)

E

B(E).

the Borel field generated by E, for each open set G E S . Baire functions may also be called Borel measurable functions. Clearly, every Baire function is measurable and every continuous function (from

IR" to S) is a Baire function. The indicator function of a measurable set that is not a

Borel set would be an example of a measurable function that is not a Baire function. The indicator function of a nontrivial proper Borel subset of IR " is an example of a Baire function that is not continuous.

.

Theorem 4.1.1 Suppose each of the functions f f 2 . . . . f n is an %-measurable real-valued function defined on X . Let (a : IR" + IR be a Baire function. Then F = @( f l , f 2 . . . . , fn) is an %-measurablefunction defined on X . Proof: We need to show that for each open set G E IR we have F - ' ( G ) E 2. Denote f = ( f l ? f 2 . . . . fn) : X IR". We claim that f is measurable. In fact, each open set 0 G JR" can be written as a union of countably many open blocks of the form n

.

-+

Z=1

which is a Cartesian product of n open intervals. Thus

f-l(B)

=

f)f,-1(a2.b,)

E

u.

Z=1

Hence f is %-measurable from X to IR", since 2l is a a-field and is thus closed under countable unions. Then F - l ( G ) = ((a o f ) - ' ( G ) = f-' ( @ - ' ( G ) ) for each open set G C JR. Since W1(G) is a Borel set, the theorem is true by the result of Exercise 4.2. We remark that in Theorem 4.1.1 it would have sufficed to have CP defined on a set D E JR" provided that (f1 , . . . , f i x ) : X + D.

Remark 4.1.1 It follows from Theorem 4.1.1 that such combinations of measurable functions as the following must be measurable: c1 f l f l

+ c2 f 2 , where c1 and c2 are constants.

. fi, the product of two measurable functions.

58

MEASURABLE FUNCTIONS

0

2,where

In particular,

f2

is nowhere zero.

is also measurable. Thus f is measurable if and only if

-fl

I f ( x ) '0 ) E for every Q. E IR. Of course, this can be seen also from the fact that f is measurable if and only i f f - ' maps open sets to measurable sets.

Corollary 4.1.1 r f f 1 and f 2 are %-measurable real-valued functions, then each of the following functions is %-measurable: i. max(fl.f.2) xE

x.

ii. min(f1. iii.

f+

f2)

= f l v fi,

where

fl

v

=

f2(.r)

m a x ( f l ( x ) . f 2 ( x )for ) each

= fl ~ f 2 wherefl , ~ f 2 ( x= ) min(fl(x). f ~ ( x )foreachr ) E

= f v 0, known

X.

as the positive part o f f .

iv. f - = (-f) v 0, known as the negative part o f f . (The reader should note that the negative part of a real-valued function is positive.) v.

If1

=

f+

+ f-.

Proof: It suffices to observe that m a x ( x 1. x2) and min(z1, x2) are both continuous functions from R2 to R, making each of these a Baire function. For the last part, we H use the fact that @(XI. x2) = x1 + x2 is continuous and thus a Baire function. EXERCISE

Show that it is possible for f : IR -+ R to be nonmeasurable and still have measurable.

4.3

4.2

if1

LIMITS OF MEASURABLE FUNCTIONS

In the study of pointwise limits of measurable functions and integrable functions. we will consider sequences of functions for which f n ( x ) diverges to +afor some values of x. Thus it is helpful to extend the concept of real numbers to the set IR* = R u { kco} of extended real numbers. Measurability for an extended realvalued function means that for each a E R, the set f-1[0,

co] = { T 1 f(.)

a } E %.

and conversely.

Theorem 4.2.1 Let ( X ,2,p ) be a measure space and let { f n I n E IN} be any sequence of measurable functions from X to IR*. Then each of the jive functions dejined as follows is %-measurable:

LIMITS OF MEASURABLE FUNCTIONS

59

i. f*(z)= inf{fn(z) I n E I N } f o t - d l s E X . ii. f * ( x ) = sup{f,(s)

I n E IN}fornlls E X.

iii. f(z)= liminf f n ( z ) f o r a l l z E X . iv. T(z)= lim sup fn ( x )for all s E X . v. f(z)= limn+L fn(s)provided the limit existsfor all z E X. Proof; For the first part, we observe that each a E JR,

f;'[a.

021 =

=

{

s

I

inf f n ( s )2 a } n

n f,-ya3

2.

nEIN

Thus f* is %-measurable. Since

f*(z)= -inf(-fn(z)). n it follows that

f* is %-measurable as well. Note next that since in

=

inf{fk(z) I k

> n)

is an increasing sequence of extended real numbers i ,,, we have

so that f is %-measurable, being the supremum of a sequence of measurable functions given asinfima. Also,

limsupf,(z) with the result that

=J(x) =

inf {sup{fk(s)

I k 3 1 2 } 172 E IN},

f is %-measurable. Finally, we note that f(z)= lim fn(z) n+ L

exists if and only if T ( x ) = f(x). Thus f is %-measurableprovided that the pointwise limit exists on X .

EXERCISE Suppose fn : X + IR is a measurable function for each n ( X ,%, p ) is a measure space. Prove that the set

4.4

is a measurable set.

E

IN, where

60

MEASURABLE FUNCTIONS

The reader should be able to give examples of pointwise convergent sequences of continuous functions for which the limit is not continuous and examples of pointwise convergent sequences of Riemann integrable functions for which the limit is not Riemann integrable. We see already that measurability must be a valuable concept for pointwise convergence since pointwise convergence does preserve measurability.

Definition 4.2.1 Let ( X ,U, p ) be a measure space, and let 's1 be the set of all null sets. Suppose P ( r )is a proposition for each x E X . Then we say that P ( r )is valid U-p almost everywhere

if and only if there is a set N E T such that x has the property P for all 3: E X\N. This is commonly expressed as p-almost everywhere, or as almost everywhere, provided that there will be no confusion as to which measure p or g-algebra U is in use.

Remark 4.2.1 Given a measurable function f , it is common to see a set-theoretic notation such as this: Let

B = inf{K E IR I If I).(

< K a.e.}.

In this notation, each of the numbers K is called an essential upper bound of f, meaning that If (.)I is bounded above by K almost everywhere. If B < a , then we denote

B = Ilflllr> the essential sup-norm o f f .

Corollary 4.2.1 Let f n be a sequence of measurablefunctions on a complete measure space ( X ,U. p). Suppose f n ( r ) f ( z )almost everywhereon X . Then thefunction f is measurable. --f

Proof: This follows from Theorem 4.2.1. It is understood in this context that although the function f is defined by the given limit, except on a null set N , f' may have arbitrary values on N itself. Then the completeness of the measure space tells us that the resulting function f remains U-pmeasurable regardless of how values are assigned to f within the null set N . w

EXERCISES 4.5 Suppose f : X + IR* is a measurable function that has finite values almost everywhere on the measure space ( X .U, p ) , where p ( X ) > 0. Prove that there is a set of positive measure on which f is bounded. 4.6 Suppose the measurable function f : IR" + IR has the special property that for each fixed vector c E IR", the translation o f f given by fc(x) = f (x c) is equal almost everywhere to f (z) itself. That is, for each value of c E IR", we have

+

SIMPLE FUNCTIONS AND EGOROFF'S THEOREM

61

for almost all 5 . Prove that f(x) is equal almost everywhere to a constant function. (Hints: Consider both the sum and the terms of

Apply Exercise 3.26 to select the special value of n. Divide and conquer!) 4.3

SIMPLE FUNCTIONS AND EGOROFF'S THEOREM

In this section we will consider both uniform convergence and what we will call almost uniform convergence of sequences of measurable functions. We begin with a useful definition that generalizes the notion of a step function from advanced calculus.

Definition 4.3.1 A function f : X + IR is called %-simple (or simple if there will be no confusion regarding the a-field U that is under consideration) if and only i f f is %-measurable and

{f(.) I 2 E XI is a finite set. The class of simple functions is denoted by 6 . Thus, f is simple if and only if we have finitely many sets

A,=f-l(cu,)~%. i = l such that

u n

X

=

. . . . .n

n

A, and f(x) =

2=1

1c y , l ~ , ( x ) . 2=1

where 1~ denotes the indicatorfunction of A. That is,

Theorem 4.3.1 E v e q bounded, %-measurable, real-valued function f is the uniform limit of a monotone nondecreasing sequence of simple functions arid also o j a monotone nonincreasing sequence of simple functions. Proof: Define f71(T)

k . If z 2n

= -

E

,4k

=f-

k

k+l

Since f is bounded, there are only finitely many values of k for which A,, # ,@. Thus f n achieves only finitely many values and is %-simple. Moreover,

62

MEASURABLE FUNCTIONS

so that f n + f uniformly on X. It is left to the reader to verify that f is in fact a monotone nondecreasing sequence of simple functions. Monotonicity follows from the method of interval bisection that is used in the definition of the sequence f n . The reader should also produce and verify the properties of a similar nonincreasing sequence of simple functions. This can be done by applying the preceding method to the function - f . H It is worth noting that even the pointwise limit of a sequence of simple functions must be measurable. Thus a bounded function is measurable if and only if it is the limit of a monotone sequence of simple functions.

EXERCISES 4.7 Prove that every %-measurable function f : X IR is the pointwise limit of a sequence of %-simple functions. Give an example to show that uniformity of convergence cannot be required in this exercise. (Hint: Proceed as in the proof of Theorem 4.3.1, but for each n define f using llcl < n2".) -+

4.8 Let f : IR" IR be Lebesgue measurable. Prove that f is equal almost everywhere to a Bore1 measurable function. (Hint: The function f is the pointwise limit of a sequence & E 6 ,the vector space of simple functions. Modify the functions an suitably.) -+

Exercise 4.7 shows that if the measurable function .f is not bounded. then we cannot expect uniform approximation by simple functions. The following theorem provides interesting additional insight into what can be guaranteed.

Theorem 4.3.2 (Egoroff) Let ( X .U.p ) be a measure space of finite total tnerisure. Let f n be U-measurablef o r each 1% E IN and suppose that f ,, + f poinruise on X . Then, for each 71 > 0, there exists a set B E U such thcit p ( B ) < 11 and such thut f n + f uniformly on X\B. Proof: Note that f must be measurable because of the hypotheses. Let define

A n ( € )= {.r

E

X 1313 3 n such that If,(.)

-

f(~)l

This set is measurable since each f, is measurable. Thus A,, Moreover, ill(€) 2 A * ( € )3 . . . 3 A n ( € 3 ) ... is a decreasing nest with emp8 intersection because f By Exercise 2.19, P(-4n(E)) 0 +

as n + cc,since p ( X ) < co.

E

2

F

> 0 and

6

% for each

TI

,, converges pointwise

E IN.

on X.

SIMPLE FUNCTIONS AND EGOROFF'STHEOREM

For each k

E

IN there exists n,k

E

63

IN such that

and such that nl < n2 < . . .. Let

2

so that p ( B ) < v. If E > 0, we can pick k such that < E . If x $ then I f n ( x )- f(.)l < E . Thus fn + f uniformly on X\B.

B and 11 3 n k ,

We remark that Egoroff's theorem is often paraphrased informally as follows: Pointwise convergence is almost uniform convergence. It is necessary, however, to understand the precise meaning of that expression as being the statement of Egoroff's theorem. It is especially important to understand that the set B must normally have strictly positive measure, albeit small measure. We give an elementary example to explain this. EXAMPLE4.1

Let fn(.) = (1 - x 2 ) n on [-1.13 for each n. E W, using the underlying Lebesgue measure space ([-1.11, C.1). Then fn + l{o) pointwise, but not uniformly, on [-1. 11. If we let B = ( -T, r ) for a small positive number T , then it is easy to see that f n + 0 uniformly on [-l>1]\B. In fact, Ilfn - ollsup =

(1 -

+

0.

with the sup-norm being calculated on [-l,l]\B. For a set B to have the effect calculated above, it must include some interval around 0 so as to exclude all sequences different from 0 but converging to 0. Thus B cannot be replaced by a null set. EXERCISE

4.9 Give an example on the real line to show that pointwise convergence of a sequence of measurable functions need not imply uniform convergence off some set of small measure. Thus finiteness of the measure space is necessary in Egoroff's theorem. 4.3.1 Double Sequences

Theorem 4.3.3 Let ( X ,Q, p ) be afinite measure space. Let { f 2 , 3 I i . j = 1 , 2 , . . .) be a double sequence of %-measurablefunctions defined on X such that lim f z , 3 ( x = ) f z ( x ) .Vx E X

&L I+

64

MEASURABLE FUNCTIONS

and lim f,(x)= f(x), Vx E X 2-

I

Then there exists an increasing sequence n , of positive integers such that

2 - p almost everywhere on X.

Proof: We can diagram the hypotheses conveniently in the form

I

(i

4

m)

f(XI. There exist B1E

for all

2 E

and n1E N such that p(B1)
0 there exists N E IN such that n 2 N implies that

It follows readily from the definition that f l L + f in measure if and only if for each E > 0 and each 17 > 0 there exists N E IN such that n 2 N implies I-L

I

{ z Ifn(x) - f

I).(

2 17) < 6 .

Thus the definition is phrased as it is for simplicity. One gains nothing that is not already there if one uses two criteria, E and 7 . EXERCISES 4.10 Let ( X .U. p ) be a measure space for which p ( X ) < m. Suppose f is a sequence of measurable functions such that f -+ f almost everywhere. Prove that f n + f in measure. (Hints: Theorem 4.3.2 is helpful. You may assume either that f is measurable or that the measure space is complete, explaining why either assumption has the same effect.) 4.11 Give an example of a sequence of Lebesgue measurable functions f -, 0 in measure on [0,1] for which the sequence of numbers f n ( r )fails to converge to zero for any z E [O. 11.

Exercise 4.1 1 adds to the significance of the theorem below. The exercise explains why, in the following theorem, we will need need to pass to a subsequence that is sufficiently rapidly convergent in measure to guarantee pointwise convergence almost everywhere.

Theorem 4.3.4 Let f and f n be measurable functions on a $finite measure space ( X ,8 .p )f o r all n. Suppose that f n + f in measure. Then there exists a subsequence f n , that converges to f alniost eveiywhere as u + a. Proof: By hypothesis, for each u that

E

IN there exists n u E IN such that n 2 nu implies

The difficulty in establishing convergence pointwise almost everywhere is that these sets can slide around and cover a big region as we vary n 2 n ”. Thus we define the

66

MEASURABLE FUNCTIONS

set

for the individual function

fn,,

and we do this for each value of v. Define

nU Y.

s = limsupE,

=

L

E,.

k=l v = k

It is easy to check that S is a null set. Moreover, x $ S if and only if 3: lies in only finitely many of the sets E,. Thus if x $ S , we know that for sufficiently big values of v corresponding to z, we have x $ E,. This implies that

It follows that for z $

S the sequence fn, (x) f (x)as v -+

-+

m.

4.4 LUSIN’S THEOREM Lusin’s theorem is paraphrased often as stating that a measurable function on RP is almost a continuousfunction. Such phrasings can be useful as reminders of theorems that could help us in certain situations. But it is very important to remember to interpret the paraphrasing of Lusin’s theorem as meaning exactly what the theorem itself states.

Theorem 4.4.1 (Lusin) Let f : X -+ IR be a measurable function defined on a Lebesgue measurable set X c IRP,f o r which the Lebesgue measure 1 ( X ) isjnite. Then for each > 0 there exists a compact subset K c X such that l(X\K) < 7 and such that f the restriction off to K, is continuous on K.

IK,

Proof: We will undertake four restrictions of domain in order to reach a compact set K on which f is continuous.

lK

i. We wish to restrict f to a bounded subset of X so that the closed approximations of measurable sets from within will be compact. We can do this as follows. Since 1 ( X ) = lim 1 ( X n [-k. kip), k+ L

there exists a closed cube Q = [-K; KIP c IRP large enough so that 77 l ( X ) 2 1(Q n X ) > l ( X ) - -. 8

ii. We know from Exercise 4.7 that f is the pointwise limit of functions the class of simple Lebesgue measurable functions. Write P,,

fn E

G,

LUSIN'S THEOREM

67

a linear combination of indicatGr functions of disjoint measurable sets A :', with X = UFZl A:. (The superscripts are labels only-not exponents.) By Exercise 3.3, for each i and n there exists a compact set K: C Q n A: such that

Each function fn is continuous on K: because it is constant there. Note also that the cluster points of K: and those of "3" for j # i must be distinct, since both sets are compact subsets of their respective disjoint measurable sets. That is, each set contains all its limit points and the two compact sets are disjoint. Thus f72 is continuous also on

Moreover

l(X\Kn) < 17

+

Pn

77

p,2n+l ~

1=1

=

'I 1 8 +2n+l'

... Define another compact set

111.

so that 17 + 'I = 5'1 l(X\K*) < 8 2 8

The functions f n are continuous on K * and the sequence f n on K * .

--f

f pointwise

iv. By Egoroff's theorem there exists a measurable set B E K * with 1(B) < and fn + f un$orormly on K*\B. Since the set K*\B is measurable, there exists a compact set K E K*\B such that 'I l((K*\B)\K) < g

which implies that l(X\K) < r j and f is continuous on K . w

IK

Lusin's theorem tells us that the restriction f is a continuous function. That In other words, f is continuous as a function defined only on the is, f E C(K.a). restricted domain, K . But f need not be continuous at any k E K as a function defined on X . This is relevant to Exercise 4.12.

68

MEASURABLE FUNCTIONS

EXERCISES 4.12 Let f be the indicator function of the set of all irrational numbers in the interval X = [O. 11. a) Show that f is nowhere continuous on [O. 11. b) Let 7 > 0 and find a set B of measure less than 11 such that f is continuous on K = X\B and such that K is compact. 4.13 Let f : [a. b] + lR be a measurable function. Let 7 > 0 and E > 0. Prove that there exists a measurable set B such that l ( B ) < 77 and a polynomial p such that sup { i f ( s )- p(.1')I 1.1' E [a. b]\B} < E .

(Hint: Apply the Tietze Extension theorem and the Weierstrass Approximation theorem.) 4.14 Use Lusin's theorem to prove that a measurable homomorphism f of the additive group of real numbers into itself must be continuous. That is, prove that if f is measurable and if f ( s+ Y) = f ( T ) + f ( y ) .

then f must be continuous. (Hints: Consider a compact subset K c [0,1] that nearly Jills [0,1] in the sense of Lebesgue measure and such that f is uniformly continuous on K . Prove that if h is sufficiently small, then K n ( K h ) is nonempty. Prove that f is continuous at 0.4')

+

'"This problem appears again in the present book as Exercise 7.7. on page I3 1. See how the problem is expressed in that exercise, and read the historical footnote following it. For that second introduction of the problem, an integration-based solution is suggested. "This method was presented in a paper by S. Banach [ I ] .

CHAPTER 5

THE INTEGRAL

We will introduce the concept of the integral, beginning with the integration of special simple functions and some easy theorems. 5.1 SPECIAL SIMPLE FUNCTIONS Throughout this section we let ( X .2;p ) be a measure space. We introduce below the concept of a special simple function which generalizes the concept of a step function in the study of the Riemann integral. Recall that a simple function is a measurable function that achieves only finitely many distinct values, all of them real.

Definition 5.1.1 The set 6 0 of special simple functions consists of those real-valued simple functions f E 6 denoted by

i=l

for which a , # 0 implies that p ( A i ) < co. Measure and Integration: A Concise Introduction to Real Andysis. By Leonard F. Richardson Copyright @ 2009 John Wiley & Sons, Inc.

69

70

THE INTEGRAL

Observe that for a special simple function, if p ( A , ) = a,then we must have at = 0. Next, we define the integral of a special simple function in the most natural way. The definition will clarify why we need to assume that p ( A , ) < m if a , # 0.

Definition 5.1.2 I f f

=

z:=,a I 1 ~ ,

E6 0 ,

we define

We adopt the convention, in Equation (5.1), that if p ( A , ) = x,so that a , = 0, then the corresponding summand, a Z p ( A L is) , to be counted as zero in the sum. We leave it for the reader to check that the integral is well defined on 6 0,despite the fact that the decomposition of such a function as a linear combination of indicator functions of measurable sets is not unique.

Theorem 5.1.1 (Linearity of the Integral) The space 6 is a vector space and the space 60is a vector space. Let I : 6 0+ IR be defined by I ( f )=

Jf

dP

X

Then I is a linear functional, meaning that I ( t r f gin6oandaEIR.

+ g ) = a I ( f )+ I ( g ) f o r cill f and

Proof: To prove that 6 0 and 6 are vector spaces, it is necessary only to prove closure under subtraction and scalar multiplication. If f and g are in either of these two spaces, we can write m

ri

i=l

j=1

We will require for convenience in this proof that n

m

UA,=X= UBI. 3=1

1=1

Hence we can write af

+g =

1

(00,

+ 3j)1A,nBJ

I N we have

< E. Thus we have proven that

jX

%: ;

f n dP = JX

f dp.

EXAMPLE5.1

Let S = { T , ~I n E IN) = Q n [0, 11. Let f n = l{rl ,...,T , L j for each n E IN. Thus I f n I 6 1 E C[O. 11 for all n and f n -+ 1s as n -+ 00. This implies by the Lebesgue Dominated Convergence theorem that 1s E C[O, 11 and that LO.ll

lsdp

=

lim

n -+ -L

LO.ll

fn

dp = 0.

However, 1s is not even Riemann integrable on [0,1].

EXERCISES

5.16 Let the graph of fn : [O. 11 + IR be an isosceles triangle with base and altitude a,. Prove that f n -+ f = 0 on [O. 11,but that

s,o, ,

fn

dp

[A. $1

-+ *

as n -+ co,provided that the sequence a, grows sufficiently rapidly as 71 increases. Thus domination (boundedness) by an integrable function is a necessary hypothesis in Theorem 5.3.1.

5.17

Let

X fn(X) = 4 n[ - n , n ] ( . d .

Find the pointwise limit f(x) = 1imrL+/ fn (x)on IR. Prove that

LEBESGUE DOMINATED CONVERGENCE THEOREM

87

Does the sequence f n satisfy the hypotheses of the Lebesgue Dominated Convergence theorem? Explain.

5.18 With respect to Lebesgue measure 1 on [O. 11, give an example of a nortmetrsuruble function f : [0,1] IR such that I f 1 E C[O. 11 and JLo,ll I f 1 dl = 1. ---f

5.19 Let f be integrable on an arbitruty measure space ( X .U, p ) . Let A n E U be an arbitrary sequence of disjoint measurable sets. In Theorem 5.2.2 we proved that

Lew

f&=

'4

cs

nEW

fdp.

An

Give an alternative proof using the Lebesgue Dominated Convergence theorem.

5.20

Let f a)

E

C[1. co)with respect to Lebesgue measure. Prove or disprove: f d l -+ 0 as b -+ l + .

sLb,x)

b) f dl -+ 0 as b -, so. c ) This is a generalization of parts (a) and (b) above. Suppose that f

E

C ( X .U, p)

is integrable on a general measure space. Prove that45 i. If E > 0, there exists a set A E U of finite measure such that

s,.

ii.

5.21

If I d P < E .

SA f d p -, 0 as p ( A ) -+ 0, where A E U. (Hint: Use the definition of C ( X .U, 1-1)in terms of bounded nonnegative measurable functions with finite carrier.)

Let

Prove that f l L -+ 0 pointwise almost everywhere. Is

dl

S, S,257 f n dl =

fn

dl?

Reconcile your conclusions with the Lebesgue Dominated Convergence theorem.

5.22

Let f

E

C(IR). Find

and justify your conclusion. "Variations on this exercise appear in Exercises 5.24 and 8.10. Compare also with Exercise 2.19

88

THE INTEGRAL

5.23

Let fn : [0, co) --+ IR be defined by X

fn(x) = - e - y

T

n

for each n E IN. Let f(x) = limn+L fn(z).Show that for all a

E

[O. a )we have

but that Explain.

5.24 Let El 3 E2 2 . . . 3 En 3 . . . be a decreasing nest of measurable sets in the complete measure space ( X ,U, p ) . Let f be integrable on ( X .a, p ) and suppose that

Prove46 that

5.25

SE,,

f dp

--+

0 as n

--+

oc.

Let f E C(R), and suppose also that ,5 Izf(x)I dl(x) < m. Define

for all Q E

IR. Prove that the derivative ~(x)cos(cIz)~~(T)

exists and find its value for all cy E IR. Observe that this problem deals with the interchange of order of two limits: the integral and the derivative. You will need to justib carefully bringing the derivative with respect to Q inside the integral. (Hints: Take a sequence hn -+ 0 and show that lim

F(Q

+ h,)

- F(cl)

hn

n-x

exists and is independent of the choice of h

--+

0.)

5.26 Let be a double sequence of real numbers having the property that there exists a sequence b, for which lam,nl < lbml for all m and 72 in IN and such that --+ A,, as n --+ co for each ni. Em lbml < m. Suppose also that a) Prove that A, = l i m C

C m

46Another proof is suggested in Exercise 8.10.

71

m

89

MONOTONE CONVERGENCE AND FATOU'S THEOREM

(Hint: Apply Lebesgue Dominated Convergence, interpreting the summation on m as being an integral over IN with respect to counting measure.) b) Give an example in which no summable sequence such as b,, exists, in which the conclusion of part (a) fails. 5.4

MONOTONE CONVERGENCE AND FATOU'S THEOREM

The following theorem extends somewhat the conclusions of the Lebesgue Dominated Convergence theorem in the case of monotone increasing sequences of nonnegative, measurable functions.

Theorem 5.4.1 (Monotone Convergence) Let ( X .U,p ) be a complete measure space, and suppose f n : X + IR is %-measurable f o r each n E IN. If each fn b 0 and if the sequence f n ( z ) is increasing monotonicaliy to the limit f ( x ) almost everywhere, then

Before proving the theorem, we observe that the Monotone Convergence theorem differs from the Lebesgue Dominated Convergence theorem in that we do not assume that the sequence f n is bounded above by an integrable function. Note that f (z) may be infinite. For example, the Monotone Convergence theorem will still apply even if f n ( z )diverges to infinity at each z, though it would assert in that case only that both sides of the equation are infinite. Proof: We know that f is measurable because it is the pointwise limit almost everywhere of measurable functions, combined with the hypothesis that the measure space is complete. If f E C ( X ,U, p ) , then the Monotone Convergence theorem is an immediate consequence of the Lebesgue Dominated Convergence theorem. Beyond the content of the Lebesgue Dominated Convergence theorem, the Monotone Convergence theorem adds only the claim that if too. Suppose therefore that

[

Jx

f dp = co then

[

Jx

f n dp

-+

m

P

J f dp = co. This means that for each 111 > 0 there X E 6 0 such that 0 < d < f and A l < ix d d p < co. Also, f n A #(z) is an

exists increasing nonnegative sequence converging almost everywhere to the dominating function f A 4(z). Thus the Lebesgue Dominated Convergence theorem implies that

Hence there exists N such that n b N implies that

r

r

90

THE INTEGRAL

This proves the theorem. As a handy application of the Monotone Convergence theorem, we prove the following result.

Theorem 5.4.2 Suppose f is measurable on ( X .Q, p), a 0-finite measure space. r f

is a decomposition into the union of an expanding nest of measurable sets of~finite measure, then

Proof: Let f n = I f 1 l,4n for each n E IN. Then f n is an increasing sequence of nonnegative measurable functions converging everywhere to f . The MonoI f 1 dp < a3 if and only tone Convergence theorem gives the conclusion that w if limn f n dp < a3.

ix

A simple application of this theorem would be to show that f ( x ) integrable on IR by showing that lirn n

rn

J

--n

1

=

1

1

+ x2

is

A dl=.rr 0. a) Use the convolution 1 - *~l ~and, Fubini's theorem, to prove that there is a measurable set C of positive measure such that 1 ( ( A x) n B) > 0 for all z E C. b) Prove that (B - A ) n Q # 0. That is, prove that the set of differences between elements of A and elements of B must include a rational number.

+

6.12 Let f : X + IR be a measurable function on the complete finite measure space ( X ,!X p ) . Suppose g(z. y) = f ( z )- f ( y ) is integrable on X x X . Show that f is integrable on X and calculate the numerical value of 1 , x x g d(p x p). 6.13 Suppose ( X .U, p ) and (Y, 93,v ) are both a-finite complete measure spaces. Suppose f E L1(X) and g E L 1 ( Y ) .Define h ( z ,Y) = f ( z ) d y ) , a n d p r o v e t h a t h E L ' ( X x Y,[email protected] x u ) .

6.14 We investigate what is called the essential uniqueness of translation-invariant measures. a) Let (IRR,C,l) be the standard Euclidean measure space with Lebesgue measure 1 defined on the a-field of Lebesgue measurable sets. By Exercise 3.24 we know that 1 is translatiowinvariant. Suppose that p is any other 0 finite measure defined and translation-invariant on C. Use Fubini's theorem to prove that p = cl for some constant c. This is called the essential uniqueness of translation-invariant measure. (Hint: To prove this with Fubini's theorem, let E E C be any set of finite measure, let Q be the unit cube, and write P(E) =

Jn.1 1Q(P) dl(Y) h;. 1 d z )&L(z).

Then write this as a double integral over the product space lR2n, and play with the translation invariance of both measures. This proof is modeled on the proof of a more general case published by Shizuo Kakutani Ll51.1

116

PRODUCT MEASURES AND FUBINI’S THEOREM

b) Let u ( E )be the number of elements in of E-meaning u ( E )is either finite or simply co-for each E E C.That is, u is [O. coo]-valued.Is u translationinvariant? Is u a constant multiple of / ? Do we have a counterexample to the essential uniqueness of translation-invariant measure on IR n? 6.15 Let f be a real-valued function on R x IR.Suppose that f(..y) is continuous in the first variable for each fixed y and that f ( z ..) is Lebesgue measurable in the second variable for each fixed 2 . Prove that f is measurable as a function on the plane. (Hint: Express f as a pointwise limit of measurable functions on the plane.) 6.16 Suppose that ( X ,U, p ) is a complete a-finite measure space, and let f be a real-valued integrable function in L ( X ,U. p) . Let 1 denote Lebesgue measure on the real line. Apply Fubini’s theorem to the space X x IR to prove that

The use of a powerful tool such as Fubini’s theorem can produce serious errors if the tool is applied in cases that do not satisfy the hypotheses of the theorem. Here are some examples. 6.17 Let X = Y = IN the set of all natural numbers, and let 2l = Q ( X ) ,the power set of the set of natural numbers. Let I-( = u be the ordinary counting measure on U, as defined in Exercises 2.15 and 5.9. a) Show that p x u is counting measure on the power set of a- x K and that p x u is a-finite. b) Define ifx=y. if.z:=y+l.

2-2-”

if z $ {y, y

+ I}.

Show that

and explain why this does not violate Fubini’s theorem. 6.18 Give an alternative solution for Exercise 5.29 by interpreting that exercise in terms of Fubini’s theorem applied to a product in which one of the factors is the counting measure. 6.19

For 2

E

IR1 and t > 0, let

It is well known that for each t > 0,

s:x

f (2, t ) dx = 1 . It is also known that

COMPARISONOF LEBESGUE A N D R I E M A N NINTEGRALS

117

af prove or disprove: If g(z, t ) = -, at

SI,I'

g(z. t ) dt dz

I'

+ J,

g(r3t ) dz d t .

What is the relevance of this example to Fubini theorem? 6.20 Let X = Y = [0,1]. Let L,L be Lebesgue measure on X and let X be counting measure on Y . Let

Show that

and explain why this does not violate Fubini's theorem. 6.3 COMPARISON OF LEBESGUE AND RIEMANN INTEGRALS

Riemann integration corresponds to the concept of Jordan measure in a manner that is similar (but not identical) to the correspondence between the Lebesgue integral and Lebesgue measure. Although it is possible for an unbounded function to be Lebesgue integrable, this cannot occur with proper Riemann integration. Moreover, proper Riemann integrals are defined only for functions with a bounded domain D . Since a bounded domain D can always be contained in a rectangular block with edges parallel to the axes, and since we can let f be identically zero on the part of the block that is outside D , we will assume that f is defined on such a block. We will denote such a block by the suggestive notation [a,b], with the understanding that a = ( a l . . . . .a,) E IR" and b = ( b l , . . . , b,) E IR". Then the symbol we have chosen for a block has the form

n n

[a,b]

=

[at bt] . 1

t=l

a Cartesian product of closed, finite intervals. Let f be any bounded real-valued function on [a.b]. Since f =: f + - f-, a difference between two nonnegative functions, it will suffice to deal with the Riemann integration of nonnegative bounded functions f . 6o Let A denote a partition of [a,b] into the union of N rectangular blocks, the interiors of which are mutually disjoint:

A

=

{[xZ,yt] Ii

=

1.. . . . N }

'We assume the reader knows from advanced calculus that the positive and negative parts of a Riemann integrable function must be Riemann integrable. See [20].

118

PRODUCT MEASURES AND FUBINI'S THEOREM

Let Axc,denote the volume of the box [xz, y,]. On each of the N blocks [x,.yz]we yt]}. We form the let m, = inf{f(z) 1 x E [x,,yt]}and M,= sup{f(z) I z E lower and upper sums

EX,.

N

and

Then we define the lower and upper Riemann integrals by Jab

-

f ( r )d r

=

sup s(A). A

which is a supremum over all possible finite partitions A of [a.b], and

Jbbf(x) dx

= inf A

,"(A).

Definition 6.3.1 A bounded real-valued function f defined on [a.b] is called Riemann integrable if and only if

la b

In the case of equality, this value is called

f (x) d ~ . ~ '

Theorem 6.3.1 (Lebesgue's theorem) A bounded real-valued function f on [a.b] is Riemantz integrable ifand only $the set ofpoints x at which f is not continuous is a Lebesgue null set. Proof: Without loss of generality, we can suppose that f is a nonnegative bounded function on [a.b], since f = f + - f-. Note that f is Riemann integrable if and only if the same is true of both f + and f - , and a similar statement applies for continuity at a point 5 . Let

C(f) = {(J.Y) I 0 6 Y 6

f(.)},

6'The reader who wishes to learn more about the Riemann integral in text, such as [20].

IR" can consult an advanced calculus

COMPARISON OF LEBESGUE AND RIEMANN INTEGRALS

119

the region between the graph o f f and the block [a.b] in the IR”. Observe that the Jordan inner and outer measure of C ( f )correspond as follows to the lower and upper Riemann integrals of f :

1

b

g(C(f))

=

V(C(~)) =

f ( x ) d s = sup

a -

J”

O p(x) - - + n(s)- = p(s)

E

E

2

2

+ n ( x )- E

126

FUNCTIONS OF A REAL VARIABLE

for each E > 0. This establishes that

u(x) = p ( x ) + n ( x )

(7.6)

It is clear that the three functions p , n , and are all monotone increasing, since any partition A of [a.x] can be extended to a partition A u {x’)of [a, x’]for .c’ > z. Note that P(A)- 4 A )= f(.) - f ( a ) for each partition A of [a, x]. Since this implies that

it follows that supp(A) A

+ f ( a ) = supn(A’) + f(x). A,

Thus

P(z) - 4 . 1

=

f(.)

-f(a).

We have shown that f can be expressed as the difference of two monotone increasing functions having the additional special property of satisfying Equation (7.6).

Remark 7.1.1 We note that the representation f(x) - f ( a ) = p(x) - n ( x ) in Theorem 7.1.1 is not unique. In fact, we could take any monotone increasing function h(x) and write

However, the reader will prove in Exercise 7.2 that only one such decomposition satisfies the requirement that ).(V

= p(x)

+ n(x).

EXERCISES

7.2 Suppose for f , as in Theorem 7.1.1, we had monotone increasing functions f and f 2 such that

1

Observe that f l (x)- p ( z ) = f2(x) - n ( z )and prove that

+ n(x) 6 (fl(4

P(Z)

- fib)) + ( f 2 ( 4

-

fZ(4)

This establishes that the decomposition in terms of p and n in Theorem 7.1.1 is minimal in the sense that f l and f 2 must increase faster than p and n do, and that the difference cancels out. as in Remark 7.1.1,

FUNCTIONS OF BOUNDED VARIATION

127

7.3 I f f is continuous on an interval [ a ?b] and has a bounded derivative in ( a , b ) , show that f is of bounded variation on [ a 3b]. Is the boundedness of f ’ necessary for f to be of bounded variation? Justify your answer. 7.4

Let

We claim that fn 7.1 and 7.2.65

E

2 but it is not in this space if n

BV[O,11 if n

=

1. See Figures

Y

Figure 7.1 f(s)= ssin

( I ) ,with envelope u ( s ) = T , 1(x) = --2.

7.5 If both f and g are in BV[a,b ] , prove that f g E B V [ a ,b]. (Caution: The product of two monotone functions need not be monotone.)

Remark 7.1.2 Let f : [a, b] -, IR be Lebesgue integrable, which is equivalent to f + and f - being Lebesgue integrable. The indejinite integral of f is given by

F ( z ) = [a= f ( t )d l ( t ) =

laZ

f + ( t )d l ( t ) -

f - ( t ) dl(t). a

which is a difference of two monotone increasing functions, so that F lies in BV[a,b]. 65These two figures are from [20].

128

FUNCTIONS OF A REAL VARIABLE

Y

1.01

-1.0

1

Figure 7.2 f(x) = .r2sin

'\ \ '

(5).with envelope u ( z ) = x2,I(s)= - r 2 .

Thus, although f E L1(IR,2,1 ) need not be Riemann integrable, the indefinite integral of f has bounded variation and is therefore Riemann integrable, being a difference of two monotone functions. These observations are significant for the theory of functions of a real variable, and they lead us to the Fundamental Theorem of Calculus for the Lebesgue integral in the next section. First, in preparation, the reader should solve the following easy exercise. EXERCISE 7.6

Give an example of a Lebesgue integrable function f on [O. 11 for which

exists for all z E [O: 11 but fails to be equal to f(x)for z

E

[0,1] n $.

7.2 A FUNDAMENTAL THEOREM FOR THE LEBESGUE INTEGRAL

Theorem 7.2.1 Let f be any Lebesgue integrable.function on [ u , b]. and dejine the indefinite integral F ( z ) by

A FUNDAMENTAL THEOREM FOR THE LEBESGUE INTEGRAL

129

for all x E [ u , b]. Then the derivative F’(z) exists for almost all x,and F ’ ( x ) = f (.r) almost evevwhere. Proof: We know that F E BV[u.b] by Remark 7.1.2. The differentiability of F ( r ) for almost all x will follow therefore from Lebesgue’s theorem (7.3.1), which we will prove in the next section.66 For now we will assume Lebesgue’s theorem and prove the remaining conclusions of Theorem 7.2.1. It will suffice to give a proof for f (z) 2 0 for all x E [ u . b],since in general

f = f + - f-. a difference of two positive integrable functions. In summary, we are assuming that F’(x) exists for almost all x, and we must prove that F ’ ( z ) = f ( z ) almost everywhere. We consider first the case in which the function f is bounded:

o
rlJ(), where J denotes an interval. Then J covers A:,s in the sense of Vitali. Hence there exists a sequence of disjoint intervals Jk E 3 such that

Since f is monotone increasing, f ( I ) and f ( J ) must always be nonnegative numbers, and

Yet it is true also that

Hence s ( p

+ E ) > rp, which implies that p + ~ r ->->1. P

S

Since we are assuming that p > 0, and because like, this implies that r 1>->1.

E

> 0 can be taken as small as we

S

which is a contradiction. We are ready to complete the proof of Theorem 7.3.1.If we let

dz)= -f(-z)

ABSOLUTELY CONTINUOUS AND SINGULAR FUNCTIONS

139

on [-b, - a ] , then g is also monotone increasing, and

D+g(-.)

=

D-f(z).

By applying Lemma 7.3.2 to g , we see that the set of points z at which

D-f(.)

> D+f(.)

is also a null set. Thus D+ f = D- f almost everywhere. Since there are four upper and lower one-sided derivatives at each point, it is necessary to consider the . + f ( z ) )and (D-f(z), D-f(z)) we remaining pairs. For the two pairs ( D + f ( z )D can emulate the proof of Lemma 7.3.2 and then replace f by g(z) = -f(-z), which is still increasing, to reverse the roles of the upper and lower right derivatives. Similar work can be done to cover the pairs ( D + f ( x )D-f(z)) , and (D-f(z),D + f ( z ) )rn.

7.4 ABSOLUTELY CONTINUOUS AND SINGULAR FUNCTIONS The concept of absolute continuily for a real-valued function of a real variable is particularly important when studying the various forms of the Fundamental Theorem of Calculus for the Lebesgue integral. We present the definition of this concept below, following a review of two more elementary concepts of continuity.

Definition 7.4.1 Let f : [a, b] + IR.Then we have the following definitions regarding f . 1. The function f is continuous at zo E [a,b] if and only if for each E > 0 there exists 6 > 0 such that z E [a: b], with 1z - 201 < 6, implies that

If(.)

- f(.o)l

< 6.

2. The function f is uniformly continuous on [a,b] if and only if for each E > 0 there exists 6 > 0 such that z and y in [a. b ] , with 12 - yI < 6, implies that

If(.) - f ( Y ) l < 6 . 3. The function f is absolutely continuous on [a3b] if and only if for each E > 0 there exists a 6 > 0 such that for each n E IN. and for each choice of

140

FUNCTIONS O F A REALVARIABLE

The reader should take note that continuity at a point is a local concept, and the E > O may depend upon where in [ a , b ] the point zo is located. Uniform continuity requires that there exist a suitable 6 corresponding to E , regardless of where in [a,b] the points z and y are located, provided they are within 6 of one another. Absolute continuity demands more, because S > 0 is required to be independent of both the location within [a,b] of the 2n points 21 y1, . . . , zn.yn and the number n E IN, provided only that

S > 0 that works in collaboration with a given

n

1

n

If we denote E

=

U[zi,y z ] in the definition of absolute continuity, then E is 1

easily Lebesgue measurable, and the definition requires that

Thus the absolute continuity o f f is commonly denoted as f < 1, which is read as f is absolutely continuous with respect to Lebesgue measure.

EXERCISES

7.9

Let

where n E IN. Prove the following conclusions. a) f is continuous at each point of [0111. b) f is uniformly continuous on [O. 11. c ) f is not absolutely continuous on [0,1] if n = 1, but f is absolutely continuous provided n > 1. (Hint: Compare with Exercise 7.4.)

7.10 I f f is absolutely continuous on [a.b], prove that f has bounded variation on [alb]. (Hint: If A is a partition of [alb], and if S c [a. b] is a finite set of points, then the variation w(A u S ) 2. .(A).) 7.11 Show that the product of two absolutely continuous functions on a closed finite interval [a. b] is absolutely continuous. Definition7.4.2 A monotone function f is said to be singular with respect to Lebesgue measure (written f 1 I ) provided that f is nonconsranr, yet f’(s)= 0 almost everywhere.

ABSOLUTELY CONTINUOUS AND SINGULAR FUNCTIONS

141

EXAMPLE7.1

We will construct a continuous, singular function f,called the Cantorfunction, on [0,1].Each number I E [O. 11 can be expressed in a ternaty e.xpansioiz: (7.9) where each coefficient a , E (0.1.2). The coefficients a , are not unique without some further restriction. For example, if we allow infinite tails of 2s and also allow l’s, this would render ternary expansions of L in a nonunique manner, since y 2 1

&=,-1. P

Thus, if a0 = 0 and if a , = 2 for all n 3 1, then L = 1 and we could have used a0 = 1 and a , = 0 for all n 3 1. The Cantor set, C, defined in Exercise 3.1 1, can be described arithmetically by prohibiting the use of the ternary digit 1 but allowing infinite tails of 2s. The effect is the removal of open middle thirds that results in the Cantor set. Thus (7.10) Notice that the relation n: 6 I’ between two points of the Cantor set, C, corresponds correctly with the same nonstrict inequality between the two corresponding sequences of ternary digits, using the lexicographic ordering. The Cantor set can be pictured as follows. Delete from [O. 11the open middle third, $’) . This deletion eliminates all 3: with ternary expansions having which is a1 = 1 and leaves two closed intervals of length each.73 Delete the open middle third from each of the two remaining pieces, which eliminates all 3’ for which the ternary expansion has a2 = 1. Continue an infinite sequence of such deletions of open middle thirds. The reader should note that the Cantor set is necessarily uncountable, because the same is true for the space of all infinite sequences on two symbols. The Cantor set includes the endpoints of the deleted open middle thirds from the construction process, but those endpoints comprise only a countable subset of the uncountable Cantor set. Thus C includes uncountably many points that are more difficult to picture mentally than the endpoints from the deleted middle thirds. The Cantor set is closed and nowhere dense. Let each L E [O. 13 be expressed as in Equation (7.9). We will define the Cantorfunction f first on the Cantor set C by the following equation. If L is in fact expanded in a ternary manner as in Equation (7.10), without the use of

(5.

73The reader should note that the numbers

and

are not excluded.

142

FUNCTIONS OF A REAL VARIABLE

Figure 7.5

Approximation to the Cantor function.

the digit 1, then x E C,and we define f(x) by means of the binary expansion

for all x E C.One can see from this definition that f is monotone increasing on C.On each of the missing open middle thirds, we define f to be locally constant. In fact, the missing open middle third ( a ~b . ~ is )defined by the requirement U N # 1 on the N t h digit, and one can conclude that f ( a ~=) f ( b ~ )which , is the constant value chosen for f on the closed interval [ U N , b ~ ]For . example, on the first deleted middle third f will be constantly equal to and on the next two deleted thirds f will be and respectively. A computer rendering of the Cantor function is shown in Figure 7.5. The computer was set to connect the plotted points. This is appropriate in the sense that the Cantor function is continuous, as the reader will prove in Exercise 7.12. However, the picture is misleading as well, since it appears as though there were places on the graph with the derivative existing but different from zero. Actually, the derivative is zero wherever it is defined. If the picture were perfect, and if one could magnify it to an arbitrary degree, the seemingly upward-sloped parts of the graph would look just like the large-scale features, consisting of horizontal segments, except on the null set that is the Cantor set.

2,

i,

ABSOLUTELY CONTINUOUS AND SINGULAR FUNCTIONS

2.0

143

i

I

t

1

1.5t

I

t

1.0,

i

I

0.5 r

t Figure 7.6

A homeomorphism that maps a measurable set to a nonmeasurable set.

EXERCISES

7.12 Show that the Cantor function f,defined in Example 7.1, maps the interval [0,1] continuously onto itself, and is a monotone increasing function for which f '(2) exists and equals zero almost everywhere, and such that f(0) = 0 and f(1) = 1. 7.13 Let f be the Cantor function and define 4(z) = f(z)+ z for all z E [0,1]. Let C denote the (middle thirds) Cantor set. (See Figure 7.6.) a) Prove that 4 : [0,1] -+[0,2] is a homeomorphism. That is, prove that 4 is injective, surjective, and biconrinuous. b) Prove that 1(@([O,l]\C)) = 1 and that 1(4(C)) = 1. c) Let P be any nonmeasurable subset of 4(C).(See Theorem 3.4.4 for the existence of P.) Prove that 4-l ( P )is a Lebesgue measurable set but not a Bore1 set. 7.14 Let ( X ,rU, p ) be a complete measure space. Suppose that $ : X -+ JR is a measurable function such that t!rl maps null sets to null sets. Prove that $-' maps measurable sets to measurable sets.74 Is the mapping in Exercise 7.13.c measurable? 7.15

a) Provide an example of a function on [O; 11that is not absolutely continuous but is of bounded variation. 74Compare this exercise with Exercise 6.6.

144

FUNCTIONS OF A REAL VARIABLE

b) Provide examples of two different continuous functions on [O, 11 that have the same derivative almost everyw9here and that are both equal to zero at 0.

Theorem 7.4.1 Let f be a monotone increasing real-valued function on [a b]. Then f’exists almost everywhere on [a. b], and we have the following conclusions: ~

i. f(z)- f ( u ) 3

1,“ f ’ d l for all z E

[a,b].

ii. Equality holds in the inequalio above ifand only iff is absoluteljl continuous. Proof: The existence of f ’ almost everywhere follows from Theorem 7.3.1. We need to prove the two parts concerning the inequality.

Thus we can pick a sequence hn we have

4

0+, and for each t at which f ’ ( t ) exists,

It follows that f ’ is equal almost everywhere to the limit of a sequence of measurable functions, which implies that f ’ is measurable. Note that each difference quotient,

is nonnegative, as is f’(t) wherever it is exists. Next, we apply Fatou’s theorem (5.4.3) as follows. For each [c, d] c (a.b ) we have

=

f(4 - f ( c )

for almost all c and d, since f is differentiable (and hence continuous) almost e~erywhere.’~In the theorem, limc+a+ f ( c ) 3 f(a)because f is monotone increasing. I f f is not continuous at a,then the inequality is true afortiori. ii. Suppose first that equality holds in the inequality of part (i). The reader will prove that f is absolutely continuous in Exercise 7.16. 751f f is continuous at c and at d, then the limit indicated will be f(d) - f ( c ) .

ABSOLUTELY CONTINUOUSAND SINGULARFUNCTIONS

145

Suppose for the opposite direction of implication that f < 1. meaning that 1 is absolutely continuous with respect to Lebesgue measure. We need to prove that equality holds in Theorem 7.4.1. Define =

so that g < 1-by

1;

f’W d l ( t ) .

Exercise 7.16 again. Now let h h’(z)= f’(z) - g’(z)

=

=

f - g, and we have

0

almost everywhere. Also, it is easy to check that h=f-g 0 there exists 6 > 0 such that for nonoverlupping subintervals [ u k ,b k ] of [ab], we have

We claim that h must be constant. Let

Then Z covers E = {x E [u, b] I h’(z) = 0) in the sense of Vitali. Hence the Vitali covering theorem (7.3.2) tells us that there exists a disjoint sequence II, E Zsuch that k€a-

Since h’

=

0 almost everywhere, we see also that [u. b]

P

u

Ik

k€m-

which implies that

Xk( I k ( = b - a. Thus

c [u, b ] .

146

FUNCTIONS OF A REAL VARIABLE

There exists N E IN such that &,N

[a? b]\

( I k (
0 such that if E is Lebesgue measurable and if 1(E) < 6, then J E If1 dl < E. (Hint: Use Definition 5.2.3.)

ABSOLUTELY CONTINUOUS AND SINGULAR FUNCTIONS

147

b) Prove that if equality holds in Theorem 7.4.1, then f is absolutely continuous.

2

7.17 Suppose that both f and lie in L1 ( [ a .b] x [c. d ] ) . Suppose also that f ( z ,?J) is absolutely continuous as a function of y for almost all fixed values of 2 . Prove that

for almost all y. Take care to establish that both sides exist. (Hint: Use Fubini's theorem to prove that

is a constant function of y.)

7.18

Let f be an absolutely continuous, real-valued function on [u. b] a) Prove Corollary 7.4.1. (Hint: Note that f need not be monotone. Use Equation (7.2) to express f as the difference between two monotone absolutely continuous functions.) b) Prove that the total variation of f on [u. b] is equal to If' l dl. (Hint: Use the result and the hint for Exercise 7.18.a to prove an inequality in one direction. Use Equation (7.3) to prove the opposite inequality.)

ss

7.19 A real-valued function f on an interval I for which there exists a constant C such that

If(.)

- f(y)l

6 Clz - YI

for all z and y in I is called a Lipschirzfinction. a) Show that a Lipschitz function is absolutely continuous. b) Show that an absolutely continuous function f on an interval is Lipschitz if and only i f f ' is essentially bounded. c ) Give an example of a Lipschitz function that does not satisfy the Mean Value Theorem for derivatives. 7.20

a) Provide an example of a function of unbounded variation on [0,1] that has a derivative equal to zero at almost all z E [O. 13. b) Provide an example of a function that is absolutely continuous on [0,1] but has an unbounded derivative. We know already that if f E L 1 [ u .b] and if F ( z ) = exists and equals f ( z ) almost everywhere. Thus

1,"f ( t )d l ( t ) , then F ' ( T ) (7.1 1)

148

FUNCTIONS OF A REAL VARIABLE

for almost all x. We have the following stronger theorem, and the reader should pause to consider why the proof is not as simple as that of Equation (7.11).

Theorem 7.4.2 (Lebesgue) Let f E L ' [ a , b]. Theti

f o r almost all x.

Proof: Suppose cy is a given constant. We define the set N, to be the minimal set such that x E [u3b]\Na implies that 1 ~ + h lirn If(t) - Ql d l ( t ) = If(x) - 4. h-0 h We know that N, is a Lebesgue null set because of Theorem 7.2.1. We nil1 show that we can choose the sets iVa independent of Q. Write the set of all rational numbers as Q = { a zI i E IN} and let N = U?EW N,,, which is a null set. Now let 13be an arbitrary real number and pick Q E Q such that

b

13 - CL < E. We apply the triangle inequality as follows:

< 2E +

;; s,

x+h

lirn

h+O+

If(t)

- a1 d l ( t ) -

If(.)

1(A n [ x - h. I + h ] ) 2h

exists and equals 1. A density point of A need not belong to A.

- 01

+

2F

ABSOLUTELY CONTINUOUS AND SINGULAR FUNCTIONS

149

EXERCISE Let A be a Lebesgue measurable subset of R of positive measure.

7.21

a) Apply Theorem 7.4.2 to the function f = 1A , the indicator function of A,

in order to prove that almost every point z E A is a density point of A. 76 b) Suppose that A and B are two sets of strictly positive measure in IR.Apply the preceding part to prove that there exists a translation by some h E lit such that [ ( ( A h ) n B ) > 0 . 7 7(Hint: Consider two density points.)

+

The following surprising congruence theorem is a fairly simple consequence of any one of the Exercises 7.21, 3.26, or 6.11.

Theorem 7.4.3 (Steinhaus) Let A and B be any hvo subsets of R having identical, finite positive measure: 1(A) = 1 ( B ) = Q and 0 < Q < co. Then there e.xist ~ M ' O sequences of mutually disjoint measurable sets A,, and B, and null sets h' and A1 such that

A

=

UA,, u N. nEN

B = U B , u nr, nEN

and there exist constants a , such that A,, Proof: The function

+ a,

= B,

f o r all 11 E IN.

+

f(z)= [ ( ( A z) n B) is a continuous function of s which approaches zero as 1x1 + x and which achieves strictly positive values at least for some T . Thus there exists a number z = u 1 which maximizes the value o f f . Let B1 = B n ( A al),and let A1 = B1 - al. Define B1 = B\B1 and A' = A\A1. If B1 and A1 happen to be null sets, we are done. If not, pick a2 which maximizes 1((A' + T ) n B1) and define Az3B2. A 2 , and B2 in the same manner as in the first step. We proceed until the process terminates (in which case we are done) or else we generate in this way two infinite sequences of sets and translation numbers. In the latter case. observe that

+

1(A,) = l(B,) + 0 as n

+ co. Let

and let

761t is interesting to compare the result of this exercise concerning density points with Exercise 3.17. "This part calls for a new proof of a theorem the reader has proven in an earlier exercise by a different method. See either Exercise 3.26 or Exercise 6.1 1.

150

FUNCTIONS OF A REAL VARIABLE

It will suffice to prove that N and AI, which must have the same measure, are null sets. Suppose this conclusion were false. Then there exists a E IR such that 1((N + a ) n A l ) > 0. But then there exists n such that

1(A,)

=

1(B,) < 1((N + u ) n A d ) .

This violates the maximality property in the choice of a n .

CHAPTER a

GENERAL COUNTABLY ADDITIVE SET FUNCTIONS

In Theorem 5.2.2 the reader saw that if f : X + IR is integrable on the measure space ( X ,8.p ) , then we can define a countably additive set function v on U by the formula

We learned that the set function v can take both positive and negative values and that v is bounded in absolute value by Ilf 1 1. In this chapter we will study general countably additive set functions that can take both positive and negative values. Such set functions are known also as signed measures. In the Radon-Nikodym theorem we will characterize all those signed measures that arise from integrals of an integrable function with respect to a measure, p, as in Equation (8. l), as being absolutely continuous with respect to the measure p. And in the Lebesgue Decomposition theorem, we will learn how to decompose any signed measure into its absolutely coritinuous and singular parts, with respect to a given measure p. These concepts for signed measures will be defined as part of the work of this chapter. Measure and Integration: A Concise Introdi~tionto Real Ana1)sis. By Leonard F. Richardson Copyright @ 2009 John Wiley & Sons. Inc.

151

152

GENERAL COUNTABLY ADDITIVE SET FUNCTIONS

8.1 HAHN DECOMPOSITION THEOREM

Definition 8.1.1 Given a a-algebra U of subsets of X , a function p : U + IR is called a countably additive set function (or a signed m e a ~ u r e ) , ~provided ' that for every sequence of mutually disjoint sets A, E U, we have

We prove first the following theorem.

Theorem 8.1.1 If p is a countably additive set function on a c-field U, theri p is bounded on U. That is, there exists a real number A1 such that Ip(A)I 6 A1 for all A E U. Proof: We begin by restating the theorem as follows, bearing in mind that p can have both positive and negative values on U, and that consequently p need not be monotone. Let p*(A) = S U P { Ip(B)I B = A, B E U}

1

for each A

E

U. The theorem asserts that p * (X) < 00.

i. We claim that both Ip(A)I and p*(A) are subadditive as functions of A E The inequality for 1p1 follows immediately from the triangle inequality for the real numbers combined with the additivity of p: If A and B are U-measurable and disjoint, then IP ( A b B ) l = M A )

+ PL(B)l 6

IP(A)I + IP(B)I.

For the second inequality, we note that if A = A bA2, a disjoint union, then p* (A) 6 p* ( A l )+ p* (A2) because if an U-measurable set B c A, then

JAB n A111 + IP(B f-Az)l l 6 p*(A1) + p*(A2).

IP(B)I 6

Here, we have used the subadditivity of Ip(B)I as a function of B. ii. We will suppose that p * ( X ) = co and deduce a contradiction. By hypothesis, p ( X ) E IR.So there exists a set B E U such that IP(B)I

'Icl(X)l+ 1 2 1.

"Some authors allow a signed measure to be e.xtended real-valued. In that case, it is necessary to require that p take at most one of the two infinite values, co or -a, in order to ensure that p is well defined on 2L We will restrict ourselves to real-valued, countably additive set functions here, however. 79Wedo not denote Ip(A)I in the form IpI(A) because the latter symbol will be given a special meaning in Definition 8.1.2.

153

HAHN DECOMPOSITION THEOREM

By the additivity of p, IAX\B)I = I P ( W - dB)I 2 IP(B)I - IP(X)l

'1.

Because B and X\B are disjoint, it follows from subadditivity that either

p * ( B )= co or p*(X\B) = co. Thus there exists B1 E U such that Ip(B1)l > 1 and p*(X\Bl) there exists B2 E U, disjoint from B1,such that

=

co. Hence

lp(B2)I > 1 and P*(X\(Bl u B2)) = (33.

This process generates an infinite sequence of mutually disjoint sets B n such that Ip(Bn)l > 1 for each n E IN. Let

so that

E

2l

(8.2)

The latter series is conditionally convergent, meaning that it is convergent but not absolutely convergent. Therefore, by a familiar exercise or theorem from advanced calculus,*' both the sum of the positive terms and the sum of the negative terms in Equation (8.2) must diverge. Hence there exists a subsequence Bnj such that

which is a contradiction. We are ready to state and prove the Hahn Decomposition theorem.

Theorem 8.1.2 (Hahn Decomposition) Let p be a countably additive set function on a a-algebra U. Then there exists a partition, X = PUN into disjoint measurable sets, with the following properties for each A E U: i. I f A E P, then we must have p ( A ) 2 0. ii. I f A E N , then p ( A ) 6 0. *Osee, for example, [20]. There it is shown that if a series is conditionally convergent, then the sum of the positive terms diverges and the sum of the negative terms diverges.

154

GENERAL COUNTABLY ADDITIVE SET FUNCTIONS

iii. The partition X = P b N is essentially unique in the following sense. If X = PI u Nl is another such decomposition, then each measurable subset of P A P’ is a p-null set, and each measurable subset of N A N’ is a p-null set. We observe that each measurable subset of P A PI has nonnegative measure, whereas each measurable subset of AV N’ has nonpositive measure. Thus the essential uniqueness criterion can be restated as follows: p ( P A P’) = 0 = /~(~‘v A N’).

Proof: Let Q

I

= S L I P { ~ ( A )A E

U).

Then 0 < Q < cc by Theorem 8.1.1 and because p(0)= 0. For each n exists An E U such that Let

P

= lirn inf

A,

=

E

W there

6fpn. p=l n=p

so that P E U and P is the set of all those z E X such that s is present in all but a finite number of the sets A,. We will show that p ( P ) = Q. First, we need the following lemma.

Lemma 8.1.1 Under the hypotheses of Theorem 8.1.2, with a defined by Equation (8.3),i f p ( B 1 ) > Q - €1 and i f p ( B 2 ) > cy - € 2 , then p ( B 1 n B2)> Q - ( € 1

+

€2).

Proof: Because p is additive, p ( ~n 1 ~

+ p ( B 2 ) - p(B1 u B2)

2 =) p(B1)

> (Q - €1) + ( a - € 2 ) - u. = a - ( € 1 + €2)

because of Equation (8.3). Letting P+4

-1

A, and H,

N, = n=p

we see that Hq 2

for all q

E

4,.

= n=p

IN. Also,

1 > a - -2P-1

HAHN DECOMPOSITION THEOREM

155

for all q E IT.By countable additivity of p, we see that

c I

P(H%)= dH1) -

P (H,\H¶+l)

9=1

/

\

N

We deduce that

1

a n - -2P-1'

[riP4)

It follows that

a-

p

1

since the union over p is the union of an increasing chain of sets. Since p is countably additive, 1 Q - ---i < p ( P )< a 29-

for all q E IN, which implies that p ( P ) = a, as claimed. Moreover, if there were a set A E U such that A4C_ P and ~ ( ~ 0, and there exists P E 2l with p ( P ) > 0, such that if A E 2l and A c P, we have X(A) 2 e p ( A ) . In the context of the proof of this lemma, we will write the conclusion of the P

lemma as an inequality as follows: X 2 ~ p . Proof: Since X < p and X is not identically zero, neither is p identically zero. We claim that there exists sufficiently small E > 0 such that the nonnegative measure ( A - €I*)+ # 0, meaning that ( A - E V ) + is strictly positive on some set. Suppose this were false. Then we would conclude from the Hahn Decomposition theorem that X(A) < E ~ ( A for) all A E U, and for all E > 0. But this would force X = 0, which would be a contradiction. Thus there exists E > 0 such that (A - ~ p ) +# 0. Hence there is a Hahn , p ( P ) > 0. Decomposition X = P b N for the signed measure X - ~ pwith since (A - t p ) + ( P )> 0. If a measurable set A c P , then (A - e p ) ( A ) 3 0. Thus there exists a set P of strictly positive p-measure, for which

158

GENERAL COUNTABLYA D D I T I V ESET FUNCTIONS

I f f E L + ( p ) ,we define p j ( A ) = iAf d p , as we did earlier, and we let L+(p.X) =

{f E L + ( p ) I p j ( A ) < X(A)VA E U } .

noting that the inequalities that define L + ( p .A) apply to all A E U. By Lemma 8.2.1, we know that there exist E > 0 and P E U, with p ( P ) > 0, and such that ElP E

L+ ( p , A),

which therefore has a nontrivial element if X is not identically zero. Even if X were zero, the set L + ( p ,A) would be nonempty since it would contain the zero function. Let Q = S U P b j ( X ) I f E L + ( P L A)}, , (Y < X ( X ) < co. Thus, for each n E N, there exists f n X ) > (Y - k. Let

so that pjn(

gn = max(f1,. . .

fn) =fl v

... v f n

E

L + ( p ,A) such that

E L + ( p , A).

Then gn is a monotone increasing sequence of measurable functions. Moreover, pg, < X and pg, ( X ) > (Y We can define g = limn gn, which is defined and finite almost everywhere,x' and we see that pg < A. We know also that , u g ( X ) = a. It will suffice to prove that pg = A. We will suppose that the latter equation is false and deduce a contradiction. Suppose that X - pg > 0, which means that X - pg is nonnegative and not the identically zero measure. Let A * = X - pg. Then A * > 0 and A * < p. By Lemma 8.2.1, we conclude that there exists E' > 0 and P' E U such that p ( P ' ) > 0, and such that A E U and A c P' imply that

i.

X(A) - p g ( A )= X*(A)3 d p ( A ) .

+

Let h = g ~ ' l p , .Then A c P'. That is

iAh d p = l A g d p + d p ( A ) for each A E U such that 3 pg

sx

+ P€'lP,.

h d p > Q, which is impossible since h must lie in L f ( p ,A). Hence The uniqueness of the Radon-Nikodym derivative up to L '-equivalence is shown in Exercise 8.6.

Remark 8.2.2 We remark that i f f E L 1( X ,U, p ) for some measure p, then f has a a-finite carrier,'* Thus in order to characterize those measures expressible in the form

X(A) =

s,

f dp, it would be appropriate to limit our attention to 0-finite measure

spaces ( X ,U, p ) . It is easy to extend the Radon-Nikodym theorem to the case in which is a a-finite measure and X is a finite measure. "Here we use the Monotone Convergence theorem, together with the finiteness of X(X). "We can take for the carrier the set I f l - l ( O . co].

RADON-NIKODYMTHEOREM

159

It is simple also to give an extension of the Radon-Nikodym theorem to signed measures because each signed measure is the difference between two positive measures. Thus the Radon-Nikodym derivative in this more general context is the difference between two Radon-Nikodym derivatives for positive measures. See Exercises 8.7 and 8.8.

EXERCISES 8.5 Let X and p be countably additive set functions. Prove that the following three statements are equivalent. a) X i p . b) Xf < p and A- < p. c)

8.6

1x1 4 IPI.

dX Show that -, the Radon-Nikodym derivative of X with respect to p in Theorem dP

8.2.1, is uniquely determined as an element of L '(X, U, p ) . 8.7 Suppose p is a a-finite measure on a a-algebra U of subsets of X. Suppose X is another a-finite measure on U such that X < p. Prove that there exists a nonnegative p-measurable function f on X such that X(A) = f dp for all A E 2. Prove that X is a finite measure if and only if f E L1 (X,5%. p ) .

lA

8.8 Suppose p is a o-finite measure on a a-algebra U of subsets of X. Suppose X is a signed real-valued measure on U such that X < p. Prove that there exists a (signed) function f E L1 (X,U, p ) such that X(A) = f dp for all A E U. 8.9 Suppose that the measures A, p , v on a measurable space (X,U) have the relationship X 0, we have a closed set F C E and an open set G 2 E such that

If p is a signed Borel measure, then we call ,u regular provided that the variation lpl (from Definition 8.1.2) be regular, under the definition for positive Borel measures. This is equivalent to both p+ and p- being regular.

Theorem 9.5.1 (Riesz-Markov-Saks-Kakutani) Let X be any compact Hausdoif space, and let C ( X )be the vector space of all continuous real-valued functions on X , equipped with the L'-norm. Then the dual space C ( X ) ' is isomorphic as a Banach space to the space M ( X ) of all finite, regular signed measures defined on the Borel jield generated by the open (01;equivalently, the closed) sets. The space 99Actually,Riesz expressed this representation as a Stieltjes integral with respect to a function of bounded variation. See, for example, [21] or [20]. '"See [23]. IolKakutani produced this theorem as part of a paper [I41 that provides a classification of all objects known as Banach lattices. 'O*The author is calling the theorem after all four mathematicians of whose contributions he is aware. However, it is common to see this theorem named after the first two of these authors.

186

EXAMPLES OF DUAL SPACES FROM MEASURE THEORY

M ( X ) will be equipped with the total variation norm, denoted by llpll. '03 The correspondence is given by

Proof:

i. We will begin by proving that the map from p -+ T, is both isometric and injective. Let p E M(X) with norm llpll, as in Exercise 8.3. Define

6~ We see that ITLL(f)l

~llpll, f so~that ~

lIT,ll

x

6 IIPII.

We would like to show equality, however, for these two norms. For this purpose, write the Hahn decomposition X = P u N , as in Theorem 8.12. Let E > 0. There exist compact sets K p and K.%rand open sets O p and O,, such that K p c P c O p and II-~V E IV C_ 0 , ~ and such that

It follows from Urysohn's lemma that there exists a continuous, real-valued function f with l l f ( l z = 1 such that

f : Kp\Oly

-+

1 and f : KN\Op

-+-1.

Observe that (CL((l~P\ON) 2 P(P) - 26

and IPI(~~.V\OP) 2

Thus

Is,S'iPI

3

I4(W - 26.

114 - 8 6

for each E > 0. Therefore (/T// b 11p((,making both norms equal Suppose now that T could be expressed by two regular Bore1 measures, / i and u.Then T - T = 0 would correspond to LL - u,and this together with the first part of the proof implies that lip - ull = 0. Hence ,u = v. It follows that the mapping from M + C ( X ) ' is an injection. '"3See Definition 8.1.2 for I/pll.

RIESZ-MARKOV-SAKS-KAKUTANI THEOREM

187

Remark 9.5.1 The main part of the proof is to show that the injection, p -+ T,, is also a surjection. The reason this is difficult to prove is that we are given a bounded linear map T : C ( X ) + IR,and we would like to determine a measure that could describe T in the manner given above. The first guess could be that if E E 23, we should let p ( E ) = T(lp,).This would not make sense, however, because the function l p , is usually not continuous, for which reason T ( l B ) is undefined. ii. We will show how we can construct a suitable measure, given a bounded linear functional T , with the temporary simplifying assumption that T is a positive operator, as in the following definition.

Definition 9.5.2 A bounded linear functional T E C ( X )' is called positive if and only if T f 2 0 for each function f that is everywhere nonnegative. The reader will need to prove, in Exercise 9.20, that each positive linear functional is also monotone, as explained in that exercise. The restriction to positive operators will be lifted in the final part of the proof. Since T has a positive, finite norm, we can assume that IlTll = 1 simply by adjusting T by a scalar factor. '04 We make this assumptioti f o r simpliciQ in what follows. We can use T to define a nonnegative function p on the family 13 of all open sets by (9.7) p ( 0 ) = sup{Tf 10 6 f 6 l o , f E C ( X ) } . Here 10 is the indicator function of the set 0.

Lemma 9.5.1 The set function 1-1 has the following properties on the set 13 of all open sets: (a) (Null Set Additivity) p ( 0 ) = 0.

(6) (Monotonicity) 0 1 c

implies that ~ ( 0 1 )6 ~ ( 0 2 ) . (c) (Subadditivity) p(O1 u 0 2 ) 6 p ( 0 1 ) p(02). 0 2

+

Proof: The first two parts we leave as an informal exercise for the reader. For the third part we reason as follows.

Let E > 0. Then there exists f E C ( X )with 0 6 f 6 1oIuo2such that

T f > p(01 u 0

2 ) - E.

Let C = f - ' [ c , 11, so that C is a compact subset of 0 1 u 0 2 . We claim that we can write C as the (not necessarily disjoint) union of closed (and thus compact) sets, C1 and Cz, such that C1 c 01 and C2 c 0 2 . '@We assume that T # 0, the zero operator, since Theorem 9.5.1 would be trivial in that case.

188

EXAMPLES OF DUAL SPACES FROM MEASURE THEORY

In fact, the boundary set d(01 n C)\O1 and the boundary set d(O2 n C)\02 are mutually disjoint subsets of C n O2 and C n 01,respectively. Since the space X is both compact and Hausdorff, there exist mutually disjoint open sets UZ E 0 2 and U1 E O1 such that d(01

n C)\Ol G U Z .

and

d(O2 n C)\Oz G U1. We can select C1 = C n 01\U2 and C2

=

C n 02\1/1.

Thus there exist continuous functions f l and f 2 such that fl E 1 on C1 and 0 6 f l 6 l o l , and fi = 1 on C2 and 0 6 f 2 6 lo2. It follows from the definition of the set C that

f

6 fl

Also, T ( f 1 )6 p(O1) and T ( f 2 )6 ~

+ f2 + 6. ~ ( 0 2 It) .follows

that

since we are assuming that I(TI(= 1. Because the inequalities (9.8) hold for m all E > 0, the lemma has been proven. Our next task is to extend the domain of p to p(X), which we do as follows. We let

p * ( E ) = inf{,u(O) 10 3, E , 0 E O } .

(9.9)

for each subset E of X. Observe that for an open set 0 we have ~ ( 0= )p * (0). Lemma 9.5.2 Thefunction p* is a Carathkodo? outer measure on the o-jield g ( X ) ,the power set o f X . Proof: We need to show that p * ( ( z l ) = 0, and that p* is monotone and countably subadditive. The first requirement is a simple consequence of the fact that 0 is open, and 10 6 0 on X. Monotonicity follows immediately from the definition of p* as an infimum. Finally, if E , E Cp(X)for each i E IN, let E > 0, and take an open set Oi 2 E, such that

RIESZ-MARKOV-SAKS-KAKUTANI THEOREM

189

It follows from Lemma 9.5.1 that for each n E IN we have

n i=l

i=l

Since this is true for all E > 0,

and this proves the lemma. The next lemma will imply that each Bore1 set is p *-measurable.

Lemma 9.5.3 Each open set 0 is p*-measurable. Proof: Since we know that p * is subadditive, it will suffice to prove for each E c X that p * ( E ) >, p * ( E n 0 ) p * ( E n 0').

+

As in the previous lemma, Equation (9.9) tells us that it will suffice to prove the inequality for every open set E . To prove this, we proceed as follows. Let E > 0. Then there exists f E C(X) with 0 6 f 6 1 ~ such ~ that 0

T f > p ( E n 0 )- E . Let C = f [ E , 11, which is a closed subset of E n 0. Similarly, there exists g E C ( X )with 0 6 g 6 lE\cand Tg > p(E\C) - E . Thus

and this implies that Tf

+ Tg 6 p ( E ) + E. Thus

+

p * ( E n 0') + p * ( E n 0 )- 2~ 6 p(E\C) p ( E n 0 ) - 2 6 0 is arbitrary.

190

EXAMPLES OF DUAL SPACES FROM MEASURE THEORY

That p* is a regular Carathtodory outer measure follows from Exercise 2.20. It follows that p* defines a regular measure on the 0-algebra of all p *-measurable subsets of X .

Lemma 9.5.4 For each f E C ( X ) ,we have

sx f

dp = T f

Proof: We may assume, without loss of generality, that f is not the constant zero function. Let E > 0, and pick a finite sequence of numbers Q , such that Qo

andsuchthatcuo < - l l f l l L Define the open set

< cu1 < . . . < CY,


( is a homomorphism of the additive circle group, R/Z, to the multiplicative group of the complex unit circle."' Especially, one must observe that Xn(S

+t)= xn(S)xTL(f).

Theorem 10.1.1 I f f E L' (T),the nth partial sum S , of its Fourier series is given bY (10.1) "'The function xn is called a character because it is continuous and it has the property that xL(x + y)

x n ( z ) x n(y) for all r ,y E IR. "'See Exercise 10.5.

=

198

TRANSLATION INVARIANCE IN REAL ANALYSIS

Y

Figure 10.1 Dirichlet kernel D , for 71 = 10.

where the Dirichlet kernel D n is defined by sin TI-

if x @ Z, ifxEZ.

( 10.2)

1

Also, J:t D , ( x )dx

=

1,f o r each n E Jh.'Iz

Remark 10.1.2 The Dirichlet kernel does not converge to zero for x bounded away from the origin. It depends for its work on rapid oscillations in sign to produce cancellations, together with most of its integral being nearly 1 over a small interval around the origin. See Figure 10.1. Proof: We observe that

"*The theorems in the present section have been adapted from the author's book [20]. Adivnced Calculus. Introduction to Linear Ana/wis.

Ati

AN ORTHONORMAL BASIS FOR L'(?r)

199

since the integrand has period 1 and can be integrated with the same result on any interval of length 1. It will suffice to prove that the sum inside the integrand is the Dirichlet kernel evaluated at x - t. We reason as follows, using Euler's formula and the sum of a geometric series: e27rzkx

C 2n

- e-27rzns

k=-n

e2~r26x - e-2ninx

k=O e-27r~nz

- e2nz(n+1)x

1- e2n2(2n+l)s 1- e 2 ~ 2 ~

e-i(2n+l)7rx

-

-

1 - e27rzz sin(2n l ) m = Dn(x). sin T X

e-lrrx

- ez(2n+1)7rx - ezrrs

+

provided that the denominator in the geometric series formula is not zero, which is equivalent to 5 $ Z. If .z E Z, then the sum is clearly 2 n 1. Finally, since we have shown above that D71.(x)= C;=-ne27i*k5, it follows

+

readily that

1

1'

D , (x)dx

=

1 for each n E

IN.

2

The following famous lemma is very useful.

Lemma 10.1.1 (Riemann-Lebesgue Lemma) I f f E L (T),then

m

-+

0

The proof of this lemma is left to Exercise 10.1. For the next lemma, note that differentiation of a function on T has the same meaning as differentiation of a periodic function of period 1 on R. The notation C P ( T ) stands for the vector space of all p-times continuously differentiable periodic functions of period 1, where p can be a natural number or 03. In particular, if f E CP(T),then its pth derivative, f ( p ) , is continuous, provided that p < a.

Lemma 10.1.2 Ler f E CP(T), where 1 6 p < X . Then (10.3) Proof: We begin by applying integration by parts to

200

TRANSLATION INVARIANCE IN REAL ANALYSIS

We iterate this argument a total of p times, obtaining ( 10.4)

Finally, we observe that for each function g E L (T),we have

It is clear that

f(p)

is integrable since it is continuous.

Theorem 10.1.2 Let f

E

CP(T), where 1 6 p < a.Then the Nthpartial sum N

converges uniformly to f on the real line. Moreover;

llsN- f l i L

G KN+-~.

f o r some constant K that is independent of N but is dependent upon f and p . Proof: It would suffice for the first part of the theorem to give a proof for p = 1, but the the first part follows from the inequality that is the second part, and that is what we will prove. Our first step will be to prove that the sequence S , is Cauchy in the sup-norm and that it converges at the rate claimed. For each n E IN and for each m 2 n we have

as n + CO. For inequality (1)we have used Equation (10.4) and the Cauchy-Schwarz inequality for 1 2 . For inequality ( 2 ) we have used both Bessel's inequality and the integral test for infinite series of positive terms. This proves that

/ISm - Snllsup G K n i - p

AN ORTHONORMAL BASIS FOR L2(T)

201

for a suitable constant, K , that is independent of n . Thus S, is uniformly convergent to some continuous function 4. Letting m -+ cn,we see that

114 - S n l l s u p

0

+

as n + co,and that the convergence takes place at the rate claimed. It remains to prove that S, -+ f or, in other words, that 4 = f . Since uniform convergence is established already, we need prove only pointwise convergence to f . We fix 2 arbitrarily and observe that

_ _2

2

ez7T(2n+l)y

- e-zT(2n+l)y

dY.

2i where we have used Euler's formula, and where we define

Next, we define Q + ( y ) = Q(y)eiTYand Q-(y)

=

Q(Y)~-~"'>

(10.5)

and the reader can check easily that each of these functions is continuous and thus integrable. Finally, we see that

-i

- f ( z )= as n

+

h

h

( Q + ( - n )- Q-(n))

+

0

co by the Riemann-Lebesgue lemma.

Theorem 10.1.3 I f f E L2(T),then

tISrL(f) - f I l 2 as n

--+

+

0

co. Consequently, we have the Plancherel identity: (10.6)

Remark 10.1.3 A celebrated theorem of Lennart Carleson [3] established that the Fourier series of any square-integrable Lebesgue measurable function must converge to f(x) pointwise except on a set of Lebesgue measure zero. However, a set of points

202

TRANSLATION INVARIANCE IN REAL ANALYSIS

can have Lebesgue measure zero and still be an uncountably infinite set. There are examples known of continuous functions f for which S,(f) is actually divt7rpenf for infinitely many values of 2 . And there is an example of a Lebesgue integrable function f for which the Fourier series diverges at each point T ! The extraordinary pathologies of Fourier series in regard to pointwise convergence, even for continuous functions, make theorems like the one we are about to prove very interesting and useful. Proof: In Exercise 10.3, the reader will show that C1(T) is dense in L L ( T ) .Let E > 0. It follows that if f E L2 (T),then there exists a function o E C1 (T) such that

Ilf - 4

2


i itself.

E

X ( P ) dY =

C1(T). Prove that

x ( u )du 2;'

must be a constant multiple of

10.6 Let TT = (IR. +)/(TZ. +) denote the rimstandard additive circle group, which is a circle of perimeter T > 0. Use the isomorphism T : IR/Z -+ R/(TZ) defined by ~ ( r=)Tx to show that

is an orthonormal basis for L 2 ( ' I T ~and ) that the Fourier series of a function f in converges uniformly to f ,just as in Theorem 10.1.2. (In the case of IR/(TZ), the interval [O. T ]plays the role of a convenient cross section for the quotient group, and a function on such a circle of perimeter T would be a periodic function on R with period T . )

CP('ITT)

10.2 CLOSED, INVARIANT SUBSPACES OF L2('IT) In this section, we will classify all the closed, translation-invariant subspaces of L 2 ( T ) .We begin with a reinterpretation of Theorem 10.1.3.

Definition 10.2.1 Let K be a set of indices, which may be either finite or infinite. Suppose there is a set of Hilbert spaces ' H k , indexed by the set K . The direct sunz

'H=@?-tFtk k€K

204

TRANSLATION INVARIANCE IN REAL ANALYSIS

of the Hilbert spaces k E K and such that

Hk

is the set of allfunctions f such that f ( k ) E

‘FIk

for each

We define a Hermitian scalar product on ‘FI by

where (.>‘)k denotes the scalar product in the Hilbert space ?-tk The reader will verify in Exercise 10.7 that the direct sum, as defined above, is a Hilbert space in its own right. Theorem 10.1.3 tells us that for each f E L 2 ( T ) ,we have

in the sense of L2-convergence, and that the set { x n 1 n E Z} is a complete orthonormal basis for L 2 ( T ) . We can interpret the latter theorem as providing a decomposition of the Hilbert space L2(?r)into the direct sum of minimal, nontrivial, mutually orthogonal, translation-invariant subspaces:

L2(W =

@ @Xn. nEZ

Each of the spaces @ y n is a one-dimensional Hilbert space consisting of all the complex scalar multiples of a single character function, x n , which does lie in L 2 ( T ) . The one-dimensionality of each space @>( guarantees that it has no nontrivial, proper, translation-invariant subspaces. It is easy to see that if S C_ Z, then (

10.7)

is a closed, translation-invariant subspace of L 2(T),We will prove that every closed, translation-invariant subspace has this same form. In words, we will prove that each closed, translation-invariant subspace of L2(T) is the direct sum of some finite or countable collection of the one-dimensional spaces of the form C x 7L. We begin with a brief introduction to the integration of Hilbert space valued functions.

10.2.1 Integration of Hilbert Space Valued Functions We begin with a brief digression in order to define the concept of the integral of a Hilbert space valued function. We have seen in Theorem 9.4.2 that the bounded linear functionals on a separable Hilbert space 3-1 correspond uniquely to the points of 3-1 itself via the bijection Tc(17)= (v.0

CLOSED, INVARIANT SUBSPACES OF

for each E

E

L2(?r)

205

'H.

Definition 10.2.2 Suppose ( X .U. p ) is a measure space and suppose that Q, mapping X to the separable Hilbert space 'FI, has the properties that the function 2

+

(77. d(.))

is p-measurable, for each fixed 71 E 'H. Suppose also that the real-valued function ll@(x)11~ lies in L 1 ( X .U, p). Then we define the Hilbert space value of the integral of @ with respect to ,LL by the equation

for each 7 E 'H. For this definition to make sense, it is necessary to show that the right side of Equation (10.8) defines a bounded linear functional

T d i ) = LY(71.4x))&4.)* so that the latter integral determines a unique vector in 'H,"4 which we call the value of the Hilbert space valued integral. This is Exercise 10.8, In the following lemma, we prove a useful generalization of the triangle inequality for the Hilbert space norm of a Hilbert space valued integral.

Lemma 10.2.1 (Triangle Inequality) Suppose that 0 : X

+ 'H satisjes

the hypothe-

ses in Definition 10.2.2. Then

where the norm on each side of the inequalif?.is the Hilbert space norin. Proof: We reason as follows, using the definition of the norm of a linear functional:

Here we have used both the definition of the Hilbert space valued integral and the Cauchy-Schwarz inequality. "'Note

that 7-1 is self-dual-a

fact that is important here.

206

TRANSLATIONINVARIANCEIN REAL ANALYSIS

10.2.2 Spectrum of a Subset of L2('IT)

Definition 10.2.3 Let E be any subset of L (T). We define the spectrum of E to be the subset o f ? given by

Theorem 10.2.1 A linear subspace V if and only if

v=

c L2 ( T) is closed and translation invariant @%I.

7EP Proof: Sufficiency is established by Exercise 10.7. We will prove necessity. To this end, denote the convolution

(10.9)

Equality (i) expresses the definition of the convolution over the circle group. Equality (ii) rewrites the right side of Equality (i) in a manner that is useful for the present argument. Since the characters of T are mu_tuallyorthogonal, it will suffice to show that for each f E V and for each 72 E Z = T, we must have f * x n E V. Let E > 0, and fix V. Observe that the mapping t -+ f - t , carrying t to the translation of f by -t, is a continuous map from T to L2(T).'15 This mapping is uniformly continuous since T is compact. Thus there exists 6 > 0 such that

The plan of the proof is to show that the convolution integral in Equation (10.9) is a limit of a finite linear combination of translations and is therefore contained within "%ee

Exercise 10.9.

CLOSED, INVARIANT SUBSPACES OF L~

the closed subspace V. Let

nz-1

(a)

207

< 6.We reason as follows, applying Lemma 10.2.1 :

.

< C E K 1= E k=O

for all sufficiently large values of 'm. This completes the proof that f * x ?, E V ,since V is closed. Hence V contains the closed linear span of all the characters in its own spectrum. The definition of the spectrum completes the proof.

Remark 10.2.1 Although we will not prove it in this book, the fact that the irreducible translation-invariant subspaces are one-dimensional is a reflection of the circle group being both abelian and compact. The real line is abelian, but noncompact, so L 2(lR) is a direct integral of one-dimensional irreducible, invariant spaces (but not a direct sum of subspaces). Harmonic analysis can be carried out on matrix groups, on Lie groups, and on locally compact Hausdorff topological groups. For groups that are compact but not abelian, minimal translation-invariant subspaces will be finite-dimensional, but they need not be one-dimensional. For groups G that are neither compact nor abelian, minimal translation-invariant spaces in the direct integral decomposition of L 2 ( G )can be infinite-dimensional. An interesting example of such an infinitedimensional, irreducible space under the action of a nonabelian, noncompact group is given in Section 10.5, where the group under consideration is the Heisenberg group. For a well written elementary introduction to topics mentioned in this remark, see the book [ 191 by Pukanszky. EXERCISES 10.7 Prove that Definition 10.2.1 makes the direct sum of an indexed family of Hilbert spaces into a Hilbert space.

10.8 Prove that Equation (10.8) determines the integral uniquely as a vector in 3-1 by identifying its action as a point in the dual space. '16Such groups play an important role in quantum mechanics.

208

TRANSLATION INVARIANCE IN REAL ANALYSIS

10.9 Let f E L2(T). Prove that the mapping t to L2(Ti').(Hint: See Exercises 9.15 and 5.43.)

-+ f - t

is a continuous map from T

10.3 SCHWARTZ FUNCTIONS: FOURIER TRANSFORM AND INVERSION The study of the representation of functions f E L (T) by Fourier series was facilitated by the study of Cx(T) first. For the real line itself, there is a special role played by the Schwartz functions, which we will define below. First, we define the characters of IR and the Fourier transform.

Definition 10.3.1 Let f E L'(IR) and let -/ E IR. We make the following definitions. i. For each

-, E IR,we define the character k-, : IR + (T.

s)

by

uy(x) = e 2 T i 7 - G Denote the set of all characters of R by

ii. Define the Fourier traitsfortn of the function f to be f :

+ @,

given by

iii. Define the inverse Fourier transform of g E L1(IR) to be

In Exercise 5.47, the reader will have proven that the Fourier transform of each function f E L'(IR) is continuous and that it vanishes at The reader should check the simple extension that the inverse Fourier transform of an L '-function has the same properties: In fact, g ( x ) = c ( - x ) . In Exercise 10.10,the reader will show that k is the abelian group of all continuous homomorphisms of (IR.+) + (T. .). We leave it as an informal and very easy exercise for the reader to prove that the integral defining the Fourier transform of each integrable function f on IR exists. The wish would be to show that

f^=f . "'This is the Riemann-Lebesgue lemma.

209

SCHWARTZ FUNCTIONS: FOURIER TRANSFORM AND INVERSION

for each f E L 1 ( W ) .However, it is not hard to give examples of integrable functions f for which f^is not integrable, leaving its inverse Fourier transform undefined. (See Exercise 10.11.) We are ready to define the family of all Schwartz ' I 8 functions on R.These functions will not share the difficulty just described for L '(R).

Definition 10.3.2 We define the set of all Schwartz functions on the real line to be

In words, Schwartz functions can be described as being those smooth functions on the line that vanish rapidly at plus and minus infinity, as does every derivative of every finite order n. The role of the index k is to ensure that the Fourier transform of each derivative of a Schwartz function vanishes more rapidly at plus and minus infinity than the reciprocal of any polynomial. The reader should check easily that every Schwartz function is integrable and that every derivative of a Schwartz function is Schwartz.

Theorem 10.3.1 The Fourier transform, : f following properties when restricted to S(K):

+

f^ f o r each f

E

L 1 ( R ) ,has the

i. The Fourier transform is a bijection of S(R) onto itself "

ii.

f^ = f f o r each f E SQR).

iii. The Fourier transform is an L2-isometn of S(R),meaning that ( 1 f 112 for each f E S(IR).

=

l

f

Proof: i. We can produce a variant of Lemma 10.1.2, applying integration by parts to show that for Schwartz functions on the real line we have ( 10.10)

for all y # 0. We see easily that

From this it follows readily that the Fourier transform f^of a Schwartz function f must be rapidly decreasing. We need to prove that f^is differentiable and that it is in ' C (IR) as well. We will apply the Lebesgue Dominated Convergence "8Schwartz functions are named for Laurent Schwartz, who lived later than the inventors of the CauchySchwarz inequality. The difference in spelling is not accidental. "'Clearly, each Schwartz function on the line is also square integrable

21 0

TRANSLATION INVARIANCE IN REAL ANALYSIS

theorem, together with the mean value inequality for complex-valued functions of a real variable.12' Select an arbitrary sequence h , + 0. It is necessary to prove that (10.11) =

-27ri(sf)(y)

by showing that this limit exists and is independent ofthe choice of h 11 + 0. We leave the verification of this to the reader in Exercise 10.15. Applying Equation

(3'

(10.1 I), and using the fact that sf E S(R),we see that f (7)+ 0 fast as l-/l + a.By mathematical induction, we establish that the Fourier transform maps S(R) into itself. We leave the proof that the Fourier transform is surjective until the end of this proof. For the second and third parts of the prooJ u,e will treatfirst the case of functions f E C: (IR),which is the linear subspace of S(R) consisting of all infinitely differentiable functions with compact support. ii. If f E Cg (R),then there exists a sufficiently big real number T > 0 such that the interval contains the support of f. By Exercise 10.6, we claim that

[-5. 5 )

as T + so. In Equality (a) we use a Hilbert space Fourier series using an orthonormal basis, and in Equality (b) we use the form of the Fourier transform for the real line (rather than the circle) on the right-hand side. The convergence claim (c) is what we will prove now for f E CiL (R). The details are as follows.

For a suitable constant c, we have

'?OThis inequality I S a special case of the Euclidean space Mean Value Theorem, interpreting f : IR,+ C as though it were R2--valued. See [20], for example.

SCHWARTZ FUNCTIONS: FOURIER TRANSFORM AND INVERSION

21 1

for all *r because f is Schwartz. Assume without loss of generality that T > 1. and define the function h E L'(IR) by

h ( y )=

sup

-,-l 1, we make the following

with C independent of n. Hence the sequence

I f n I is dominated in the sense of the h

I

,

Lebesgue Dominated Convergence theorem, with the same being true of It follows that

Ifn 1’. h

,

I

Also,

Hence the Fourier transform is an isometric injection of S(IR)into itself, and we can see that this transformation is surjective by Exercise 10.13.b.

EXERCISES 10.10 Prove that the set 6 is an abelian group under the operation of pointwise multiplication, and that every continuous homomorphism of the additive group (IR. +) to the multiplicative group (T) .) of the complex unit circle is an element of 6. (Hint: If x is any nontrivial homomorphism of of (IR,+) .+ (T, then it has a discrete kernel, ker( x) = PZ for some positive real number p. Now consider the nonstandard circle, R/pZ.) e),

CLOSED, INVARIANT SUBSPACES OF

10.11

Find and justify an example of a function f

10.12

Let p be any polynomial, c > 0, and zo

E

E

L2((IR)

L ‘(a) for which

213

7$ L’(IR).

JR. Show that

is a Schwartz function. 10.13 Define the function 6, : JR -+ R. by 6,z = cz for each c E IR.Prove that,for each Schwartzfunction f E S(IR)we havethe following identities: ” A

A h

a) f = f 0 6 - , .

-

h

,. A

b) f = f. This is sometimes expressed with the operator equation h4 =

I,

the identity operator. In words, the fourth power of the Fourier transform is the identity operator. (This exercise may prompt the reader to search for eigenfunctions of the Fourier transform operator, corresponding to the four complex roots of unity. In fact the Hermite functions, which are the

up to a constant factor, are eigenfunctions. The reader can learn more about this in [ 5 ] , in which it is shown that h,, is an eigenfunction for the eigenvalue (4) .) 10.14

If f and g are in S(IR),show that

(See Exercise 6.7.b.) 10.15

Prove Equation (10.1I ) for every function f

E

S(IR).

10.4 CLOSED, INVARIANT SUBSPACES OF L2(lR) We will begin by defining the Fourier transform of each f E L (IR) by means of Schwartz approximations. Then we will use the L2-Fourier transform to classify all the closed, translation-invariant subspaces of L (IR).

10.4.1 The Fourier Transform in L2(IR) We caution the reader that we cannot define

214

TRANSLATION INVARIANCE IN REAL ANALYSIS

since L2(IR) Q L1(IR), and thus the integral need not exist. This deficiency can be remedied, thanks to the density of S(R) in L2(JR).

Lemma 10.4.1 The vector space S(IR)of Schwartz functions is dense in the Hilbert space in L 2(IR). Proof: It will suffice to prove that C: is dense in L2(IR). We have shown. in Exercise 5.41, that the space S of step functions'*' is dense in L1(IR). This implies that S is dense in L 2(IR) as well, since each integral of a nonnegative function is the supremum of the integrals of its truncations in both domain and range. Very much as we did for Equation (10.12), in the proof of Theorem 10.3.1, we can construct a C: (IR)-function d that comes as close as we like in L2-norm to any given indicator function of an interval, and hence as close as we like to any step function f . The method is to provide a C -interpolation between any two arbitrary heights, a and b, over a width in the domain that is positive but as small as desired. In this manner, a square integrable step function can be approximated as closely as desired by means of a Cf -function, completing the proof of the lemma.

If we take a sequence of Schwartz functions f n such that llfn - f 112 + 0, then is also L2the fact that f n is Cauchy in the L2-norm implies that the sequence Cauchy, thanks to Theorem 10.3.1. We make the following definition, which will require justification.

Definition 10.4.1 For f E L2(IR), we define f^ to be the L2-limit of sequence of Schwartz functions f n -+ f in the L2-norm.

for each

It should be noted that we have not defined f^ pointwise as a function of 7 E IR. Rather, we have defined the Fourier transform as an L 2-equivalenceclass by invoking the completeness of L2. We must show that this definition is independent of the choice of the sequence of Schwartz functions f n . Also, we have at this point two different definitions of the Fourier transform for those functions that are in L '(R) n L2(IR), and these must be shown to agree.

Lemma 10.4.2 r f f n and g n are any wo sequences of Schwartz functions converging in the L2-norm to f , then lim f r l = liin h

n-+

f

n-+ f

as elements ofL2(IR). Proof: Applying Theorem 10.3.1 again, we see that

'"The reader should take care not to confuse the space S of step functions with the space S(R) of Schwartz functions. "'See Exercise 5.62 in [20] for the details of this useful technique.

CLOSED. INVARIANT SUBSPACES OF

L2 (IR)

215

Corollary 10.4.1 The Fourier transform is a linear isometry of L2(IR)onto itself: Moreovel; the inverse Fourier transform, denoted by -, is a well-defined isotnetric surjection of L2(IR). Both transform preserve the Hermitian scalar product, arid this is called Parseval's Identity for L2(IR). Proof: If we have Schwartzfunctions f ,, -+ f and y,, and

+

(uf 9)-

=

-+g, then

n f n +gn

-+ ci f

+g,

+

lirn ( n f n g n ) ^

n+

f

proving linearity. The Fourier transform is an L '-isometry because

To see that the Fourier transform is a surjection from L 2 onto itself, let f E L 2 ( R ) be arbitrary. We pick Schwartz functions f l l + f , and we invoke Exercise 10.13.b. which tells us that

Thus f lies in the range of the Fourier transform. This shows also also that the fourth power of the Fourier transform is equal to the identity operator on L 2(IR), just as it is on S(IR).Moreover, the third power of the Fourier transform must be the inverse h

Fourier transform: 9' = $ for all g E L2(IR). The final conclusion follows from the Parallelogram Law, which determines the Hermitian scalar product of a complex inner product space in terms of its associated norm. We should note that i f f E L1(IR) n L2(IR),then we have defined f i n two distinct ways: first as an integral and then as a limit of transforms of Schwartz functions. The following lemma establishes that these two definitions for the Fourier transform of such a function coincide.

Lemma 10.4.3 For each f E L1(IR) n L 2 ( R ) ,the L'-Fourier trarzsforni of ,f is equal almost everywhere to iRf (x)e-2n2*/s dx. Proof: Let f N = f 1L - N , N ] for each N norms of both L1and L to f. Denote

E

IN. We see that fav converges in the

216

TRANSLATION INVARIANCEIN REAL ANALYSIS

the L1-Fourier transform of f , ~ iebesgue . Dominated Convergence tells us that f~ -+ the L1-Fourier transform o f f . From Lemma 5.5.1 concerning the pointwise convergence of rapidly L l-Cauchy sequences, we know that there is a subsequence f>~ that , converges pointwise almost everywhere to the L ’-transform o f f . However, , in L 2 since fnr, converges also in the L2-norm to f , the L2-transforms f ~ , converge norm to f . Passing to a suitable subsequence again (as in the proof of completeness of LP) would ensure pointwise convergence almost everywhere to a function in the L2-equivalence class of the L2-Fourier transform of f . Thus it would suffice to know that for the compactly supported function f , ~ , the L1- and L2-Fourier transforms coincide. To this end, pick a sequence q T L in C’ [-N. N ] that converges L 2 to f . ~Note . that h

7,

h

h

h

x,)

(On.

-+

(fN.

X?>

and that the latter Hermitian scalar product is the L1-Fourier transform of f,\, expressed in terms of the scalar product for L2[-N. AT]. Here we benefit from the fact that the characters x-,E L2[-N. N ] .though they do not belong to L2(IR). By passing implicitly to a subsequence in n if needed, we can assume without loss of generality that h

for almost all 7 . But since pn converges L 2 to f N , we have & convergingin the L2norm to the L2-transform f ~ Passing . again, as needed, to a suitable subsequence, we get pointwise convergence almost everywhere. Thus the two concepts of Fourier transform for f N agree almost everywhere, and the proof is complete. h

10.4.2 Translation-Invariant Subspaces of L2(R) If H is a nontrivial closed, proper subspace of L 2 ( R ) , then Exercise 9.19 ensures that H has an orthogonal complement H such that L2(IR) = H @ H I . If H is a translation-invariant subspace, then the reader will show in Exercise 10.16 that this implies the translation invariance of H I as well.

Lemma 10.4.4 Let E be any Lebesgue measurable subset of the real line, R,and let H = { ~ E L ~ ( I R ) I ~ ( ~ ) on = OE~C~= R \ E } .

(10.13)

Then H is a closed, translation-invariant subspace of L 2 ( R ) , and we call E the spectrum, H , of the closed, trarzslatiori-invariant subspace H . h

Another measurable set, E’, would have the property that 2 = E’if and only if 1(E A E’) = 0, so that E E’. That is, the spectrum of a closed, translationinvariant subspace of L2(JR)is determined up to a null set.

-

CLOSED, INVARIANT SUBSPACES OF

LZ(R)

217

Proof: Recall that the Fourier transfmm is an isometry of L2(IR). It follows that -+ if f n + f is any Cauchy sequence in H, then f n is Cauchy as well, and in L2-norm. Some subsequence of f n is pointwise convergent almost everywhere. This implies that f^((r) = 0 almost everywhere on E C ,so that f E H, which is thus shown to be closed. We claim that H is translation-invariant as well. Let f E H and take any sequence of Schwartz functions f n + f in the L2-norm. For each real number a. denote f a ( x )= f ( r a ) , the translation o f f by a. Then ii( f n ) a - fal12 -+ 0 as well. But h

h

f

+

h

It follows again by a subsequence argument that f Q ( y ) = 0 almost everywhere on E C ,proving that f a E H. rn The next theorem asserts that every closed, translation-invariant subspace of L 2 ( ( a ) is determined by its spectrum, as in Equation (10.13). This will yield a bijection between the family of all closed, translation-invariant subspaces of L 2 ( R ) and the metric space of measurable subsets of IR,in which two sets are identified if the measure of their symmetric difference is zero.

Theorem 10.4.1 For each closed, translation-invariant subspace H in L '((a), there ?-. is a measurable set E, determined up to a null set, which serves as the spectrum, H , of H as in Equation ( 10.13). Proof: Let H be any closed, proper, nontrivial, translation-invariant subspace of L 2 ( R ) . Then L2((a)= H @ ' H

by Exercise 9.19. For each vector f E L 2 ( R ) , there exists a unique decomposition of the form f = Pf + P'f, where Pf E H and P'f E HI.The mappings P and 'P are called the orthogonalprojections onto H and H', respectively. Since L 2 ( R ) is separable, there exists a countable dense subset f n , and the reader will show in Exercise 10.17 that the set { P f n I n E K} is dense in H. Thus H is separable, and it has an orthonormal basis { e n 1 n E IN}. Define a measurable set

E=

u {rE(aIG(;;(?)fO}

nEIN

Note that for each f

E

H,

f

=

c

( f . en> e n .

nEN h

an L2-convergentsum, so that f l E C = 0 almost everywhere. We need to show that i f f E L2 ((a )is chosen subject only to the requirement that f = 0 almost everywhere on EC,then f E H, implying that E is the spectrum, fi, of H. To this end, let g = f - Ce,,. h

nEK

218

TRANSLATION INVARIANCE IN REAL ANALYSIS

and it will suffice to prove that g = 0. We know at this point that s^ = 0 on E', so it will suffice to prove that = 0 as well. As we have observed earlier, for each

$IE

= x? (y) Q^(r) almost everywhere. So translation of an L 2 function 4 by y, z(7) take 4 E H and recall that, by its definition, g E HI.Thus, by Parseval's Identity (Corollary 10.4.1) for L2(JR),'24

0 = (9.P d = =

@.

.>

x7(?4)

S,

~(y)

e - 2 ~ zd?~ ~

h

for all y E IR. Thus G @ = 0 almost everywhere, including on E . Since q~ was arbitrary, and could have been any of the functions e for example, it follows that $ = 0 even on E , so that g = 0.

10.4.3 The Fourier Transform and Direct Integrals In Theorem 10.2.1, we showed how to decompose L 2 (T ) into the direct sum of one-dimensional, translation-invariant subspaces of L (T), Each one-dimensional translation-invariant subspace of L'(T) is called also an irreducible translationinvariant subspace, because it has no proper, closed, nontrivial, translation-invariant subspaces. Indeed, each of the one-dimensional spaces has no nontrivial, proper subspaces at all. We will see that the direct sum of Hilbert spaces, as defined in Definition 10.2.1, is a special case of the concept of a direct integral of Hilbert spaces.

Definition 10.4.2 Let ( A .9, p ) be a measure space. Suppose there is a set of Hilbert spaces 7-1, indexed by the set A. The direct integral

1,

0

'Ft

=

7-1, dp

of the Hilbert spaces H, is the set of allfunctions f such that f(a) E 'Ft, for each a E A and such that

We define a Hermitian scalar product on 7-1 by

"'Here we use the Fourier transform according to Definition 10.4.1-not in the sense of an abstract Fourier transform in any separable Hilbert space with respect to a specified orthonormal basis.

IRREDUCIBILITY OF L z ( R )UNDER TRANSLATIONS AND ROTATIONS

219

where (.*.)a denotes the Hermitian scaldr product in the Hilbert space Z a ,and where // . /la denotes the corresponding Hilbert space norm. The reader will show in Exercise 10.18 that the direct integral is itself a Hilbert space. Moreover, the direct sum is a special case of the direct integral, in which the measure p is counting measure on a countable space. Thus we see that the Fourier transform provides a decomposition of L 2 ( T )as a countable, discrete direct integral of irreducible, closed, translation-invariant subspaces of L (T) itself. The situation is different for L2(R). Here the Fourier transform provides an isomorphism of Hilbert spaces between L2(R)and the direct integral over the real line of one-dimensional, irreducible, translation-invariant spaces H a = (Exa.Thus

However, it is important to note that the spaces H , are not subspaces of L2(lR),since each nonzero function in H , has constant modulus. Thus the Fourier transform in L2(R)leads one to a more abstract version of harmonic analysis in which the original space, L 2(R), is analyzed in terms of irreducible, translation-invariant spaces that exist only externally to that original space. EXERCISES

10.16 If H is any closed, translation-invariant subspace of L 2 (R),then H I is also closed and translation-invariant. (Hint: Use the fact that Lebesgue measure is translation-invariant. 10.17 ble.

Show that each closed vector subspace of separable Hilbert space is separa-

10.18 a) Prove that the direct integral of a Hilbert spaces, as in Definition 10.4.2, is

itself a Hilbert space with respect to the scalar product from that definition. b) Show that the direct sum of Hilbert spaces in Definition 10.2.1 is a special case of the direct integral of Hilbert spaces. 10.5 IRREDUCIBILITY OF L2(R) UNDER TRANSLATIONS AND ROTATIONS It is a consequence of Theorem 10.4.1 that every nontrivial, closed, proper, translationinvariant subspace of L (R) has nontrivial closed, proper, translation-invariant subspaces. Here we will show that if we act upon L2(R) with all trunslatioiis and rotations, then L 2(R) has no nontrivial, closed, invariant subspaces. That is, we will show that L2(lR)is irreducible with respect to the combined action of translations and rotations.

220

TRANSLATION INVARIANCE IN REAL ANALYSIS

By rotations, in this context, we niean all operators that act on functions f E L '(R) by multiplication AIxO by a character x n (x)= e2xzas. Thus

(M,,f)I.(

= xn(.)f(.)

for all x E IR. A rotation rotates the values of f in the complex plane. The reader should note easily that AI, does map L2(IR)into itself. Thus we will prove here that if H is a closed, nontrivial subspace of L'(IR) that is invariant under all translations and all multiplications by characters, then H = L2(IR). After this work is done, we will explain the connection of this theorem with the Heisenberg group, the Heisenberg Uncertainty Principle, the Schrodinger model of the position and momentum operators in quantum mechanics, and a theorem of Stone and von Neumann.

Theorem 10.5.1 Let H be any closed, nontrivial subspace of L (IR) that is invariant under the actions of all the multiplications AIxc>(f)(x)= x a ( a . ) f ( x and ) invariant under all the translations T,(f)(t) = f(t x). Then H = L'(R).

+

Proof: By Theorem 10.4.1, there exists a measurable set I?, called the spectrum of H, such that H = {f E L2(IR) = 0a.e.).

I ylzc

We need to prove that I?" is a Lebesgue null set. Suppose that 1 H" > 0. We will deduce a contradiction. Since H is nontrivial, there exists a function f # 0 E L'(IR) for which f E H. Thus the set S f = Q E IR T(a) # 0) has strictly positive Lebesgue measure. We

( A)

{

I

know from any one of the Exercises 3.26, 6.1 1, or 7.21 ' 2 5 that there exists such that We claim that

9 E IR

(wJ)-(Q) = f(Q - PI. h

for almost all a. This would imply that S(Af,,f)

=

Bf

sf.

For functions in L1(IR) this follows immediately from the definition of the Fourier transform. I f f E L 2 ( R )we can define f n = so that fn lies in L1 (IR) for each n and fn + f in the L2-norm. By passing to a suitable subsequence fn, of the sequence fn, we can be assured that f T t z +. f almost everywhere as well, and this proves the claim. The proof of the theorem is complete, since AI,,f E H and because r?" is disjoint H from r?.

fl[-n, n l,

125Thereader may enjoy noting how any one of the measure-theoretic exercises cited here can play the crucial role in the proof of this theorem.

IRREDUCIBILITY OF L 2 ( R )UNDER TRANSLATIONS AND ROTATIONS

221

10.5.1 Position and Momentum Operators It is natural to consider the action of IR by translation upon L2(IR),but the reader may wonder why we consider here the combined actions of translation and rotation on L2(IR). In order to address this question, we present a brief description of the quantum mechanical formalism for the position and momentum operators of one isolated quantum (particle) having only one degree of freedom, meaning that it is able to move only along the real line, IR. Our discussion is only a sketch, and we will not concern ourselves with physical constants, however important, treating them as though they were 1 wherever this is convenient. Our main purpose is to explain how the combined action of translations and rotations stems from the action of a nonabelian group, called the Heisenberg group, on L 2(IR) and what this action has to do with physics. The state of the particle is interpreted as being a complex-valued function (2 in L2(lR),having the additional property that 110112 = 1. This makes 1#12 into a probability density function, meaning that the probability that the position .c of the quantum is between the coordinates a and b is given by

s,

b

P ( a 6 z 6 b) =

\d(z)l2d r .

The expected value of the position is given by

It is thus natural to define the position operator P by

( P 9 ) ( r )= X&(.)> so that the expectation of the position is (PQ. &), and this scalar product is a real number, although the function 4 is complex-valued. Note that the domain of P is D p = {O E

1

L2(IR) zq E L2(IR)}

and that this is a dense, but not closed, subspace of L (IR). Conceptually, the quantum can be regarded as beirig the state function 0,and it can be interpreted as being present at all locations in the support of d. Probability enters the picture as soon as one makes a macroscopic observation or measurement to try to detect the presence of the quantum. As evidence for this abstract notion of the position of a particle, physicists cite an experiment in which a single quantum is released on one side of a barrier that has two parallel slits cut into it. If one places detectors at the two slits, it will turn out that the quantum passes through either one slit or the other-not through both. The probability of the quantum being located at either slit is governed by the probability distribution 9.However, if no detectors are placed at the slits and a detection screen is placed opposite the wall that separates the quantum from the detector, then it turns out that a diffraction pattern appears

222

TRANSLATION INVARIANCE IN REAL ANALYSIS

on the screen. The pattern that is produced shows that the quantum has passed wave-like through both slits, creating a diffraction pattern on the detection screen by interference with itself. The Fourier transform d~permits one to express d as an integral of characters xL,. Each index u corresponds to a pure frequency having an energy level E = Itv, h being Planck's constant. The index v is taken also as corresponding to momentum.

I ^I2

= 1, thanks to the Plancherel identity. Thus d~ is a probability We note that 2 density function. The probability that the momentum A1 is between a and b is 0' wen by

The expected value of the momentum is given by

-

However,

Hence we define the momentum operator Q by QO =

-i -@I.

27r

and the domain DQ of Q is the set of those square integrable functions @ such that the derivative 4' exists and is square integrable. This domain is a dense, but not closed, subspace of L2(R).The reader will prove in Exercise 10.19 that

PQ - Q P

2

i 2T

(10.14)

-I.

where I is the identity operator, restricted to the domain

D

= Q-l ( D p )n P-l

(DQ)

According to the Heisenberg Uncertainty Principle, the failure of the operators P and Q to commute with one another means that the result of the combination of position and momentum operators is dependent upon the order in which the two operators are applied. Physically, each measurement (of position or momentum) alters the subsequent measurement of the other. Thus it matters which operation is performed first and which second. 10.5.2 The Heisenberg Group In our brief survey of the quantum mechanical formalism for position and momentum, we have derived Equation (10.14) from the definitions given here for the position

IRREDUCIBILITY OF

L2(R) UNDER TRANSLATIONSAND ROTATIONS

223

and momentum operators, P and Q, respectively. More generally, Equation (10.14) is taken as fundamental, and the formulas given here for P and Q are Schrodinger’s model (concrete realization, or example) of operators satisfying the Heisenberg Commutation Relation. A fundamental mathematical question that arises is whether or not Schrodinger’s model is unique in some suitable sense as an operator solution to Equation (10.14). The Heisenberg group, IH,is the group of all real matrices of the form

with the operation being ordinary matrix multiplication. Since these upper-triangular matrices depend only upon the three real parameters s. y, and z , we denote the matrix by the more efficient symbol (x.y, z ) , understanding this to represent the full 3 x 3 matrix. The reader should check easily that the multiplication in the Heisenberg group is given by (s, y. 2 ) (XI.y’, z’) =

(x + d.y + y/. z

+ z/ +q/)

and that this multiplication is nonabelian. (See Exercises 10.20 and 10.21.) For each (z. y. z ) E JH, we define the following action on L2(IR):

where Txdenotes translation by x and Adxudenotes multiplication by the character xy. Of course, L2-functions are defined only almost everywhere, so the preceding equation should be understood as applying pointwise almost everywhere. The reader will show in Exercise 10.22 that T is a continuous homomorphism of the group JH into the group of norm-preserving Hilbert space automorphisms of L 2(R). We see ~ %all~ x) E IR include all translation operators on at once that the operators T ( ~ , for L2(IR). The operators 7r(o.y,o)provide all the rotation operators. Theorem 10.5.1 tells us that L 2 ( R )has no nontrivial closed, proper invariant subspaces under the action of 7r. The representation i7 is said to be irreducible because of the absence of nontrivial, closed, T-invariant subspaces. It is called unitary because i7 acts in such a way as to preserve the Hermitian scalar product of L 2(IR). It is a simple calculation to show that

p = --a

27rzay

1

y=o

T(O.y.0)

and

(10.16)

Here it must be understood again that P and Q are defined only on that dense subspace of L2(IR) consisting of functions that have images under P and Q that remain in L2(IR). We see that the position and momentum operators of Schrodinger arise

224

TRANSLATION INVARIANCE IN REAL ANALYSIS

naturally by differentiation of the iepresentation 7r of the Heisenberg group, 13. In this context, the uniqueness property of the Schrodinger model for the solution operators P and Q of the Heisenberg Commutation Relation is established by a famous theorem of Stone and von Neumann. This theorem asserts that the representation 7i is determined uniquely up to isomorphism of Hilbert space by its restriction to the center 2 ( H ) = ( ( 0 . 0 . 2 ) I 2 E IR}. In other words, any other representation 0,having the same restriction to the center, must have the property that there is an isomorphism 7- of Hilbert space such that

= C(.Z.y.z) 0 T

7- O 7 r ( z s y s t )

for all (z?y. i )E IH. The reader who would like to study carefully the ideas sketched in the present section is referred to [191 and 141.

EXERCISES 10.19

Prove Equation (10.14) by showing that

the Heisenberg Commutation Relation for the position and momentum operators in quantum mechanics.

10.20 Show that the Heisenberg group is a nonabelian group, closed under both multiplication and inversion. 10.21 Show that Lebesgue measure on R 3 is invariant under the operation of right translation by an arbitrary element of the Heisenberg group. That is, define for each point ( a , b. c) in IR3, the mapping T(a,b.c) : IR3 + JR3 by

T(a.b,c)(~, y. Z ) = (X + a , y + b, 2

+c +Xb).

Show that this map preserves both Lebesgue measurability and Lebesgue measure. Show that Lebesgue measure is invariant under left translation as well.

10.22 Show that the action 7i defined by Equation (10.15) is a homomorphism of the multiplicative group IH into the group of all norm-preserving Hilbert space automorphisms of the space L2(IR).In particular, show that 7 r ( , , y , t ) ~ ( d , y / d ) = T(,+,‘,

y+y’.

Z+Z’+TY’).

and show that 7r is continuous in the sense that l l ~ ( , . ~-, ~ ql12 ) q-+ 0 for each 4 E L2(R),as (z. y , z ) + (0.0.0) in the sense of convergence in IR3.

10.23

Prove Equations (10.16) by direct calculation.

APPENDIX: THE BANACH-TARSKI THEOREM

A.1 THE LIMITS TO COUNTABLE ADDITIVITY

In Section 1.1, we considered the pivotal role of the discovery of incommensurable line segments in the development of Euclidean geometry. We identified commensurability problems as belonging to the early development of measure theory. In the pages that followed, we have learned much about Lebesgue’s theory of measure and integration. We have seen how the Lebesgue theory yields complete normed linear spaces such as LP(X.8.p). We have learned about the dual spaces of the latter spaces, and about the dual of the space C ( X ) ,if X is a compact Hausdorff space. It would be difficult to overstate the importance of Lebesgue measure and integration throughout modern pure and applied analysis. The reader has seen that much effort must be made to ensure that we deal only with measurable sets and measurable functions in Lebesgue’s theory. We showed in Example 3.1, using the Axiom of Choice, that no translation-invariant. countably additive measure can be defined on all the subsets E E IR if 0 < p[O, 1) < cc Measure arid Integration: A Corzcise Introduction to Real Aiialwis. By Leonard F. Richardson Copyright @ 2009 John Wiley & Sons, Inc.

225

226

THE BANACH-TARSKI THEOREM

In this appendix, we will discuss a theorem that is as challenging for modem mathematicians as incommensurable line segments were for their ancient Greek forerunners. It is a theorem of Banach and Tarski, and it is often called the BanachTarski Paradox. It is not a paradox in fact, but a theorem. This theorem is described as a paradox because of the extraordinarily counterintuitive nature of its conclusions. We begin with a definition.

Definition A . l . l Two sets A and B in a metric space ( X ,p ) are said to be congruent by finite decomposition provided that there is a natural number n such that it is possible to decompose A and B into disjoint unions

in such a way that Ak and Bk are congruent for each k

< n. This is denoted by

f

A 2 B. Congruence means that there exists a bijection Tk : Ak

+ Bk

such that

p ( x . y) = p ( T k . E . T k y )

for all z and y in Ak. Such a mapping Tk is also called a bijective isometp. We denote congruence as Ak Z Bk. We call A and B congruent by coiintable decomposition provided that the decomposition of A and B into mutually congruent pieces can be accomplished by using countably many pieces. This is denoted by

A

2 B.

One may prove readily as an exercise that a linear isometry of Euclidean space must preserve the measure of any Lebesgue measurable set. The reader will note that Steinhaus's' theorem (7.4.3) shows that two sets of the same Lebesgue measure in the real line must be congruent by countable decomposition. The Banach-Tarski theorem is much more startling.

Theorem A.l.l (Banach-Tarski) Let A and B be two subsets of Rn, each having f

nonempty interior, and with n 2 3. Then A 2 B. (For example, any two spherical balls are congruent by3nite decomposition regardless of the difference in their radii.) For dimensions 1 and 2 , A & B. We remark that this theorem implies that for R", with n 2 3, there cannot exist even afinitely additive measure defined on all subsets that is invariant under Euclidean ' A s an historical sidelight, we remark that Steinhaus played a pivotal role in Banach's decision to become a professional mathematician. Further information is available in [ 171.

THE LIMITS TO COUNTABLE ADDITIVITY

227

motions. For n = 1 or n = 2 , there is no countably additive measure that is defined on all subsets that is invariant under Euclidean motions. That is, in each of these two sets of circumstances, nonmeasurable sets must exist. The proof given by Banach and Tarski can be found in their original paper [ 2 ] . There is also a modern treatise on the subject [25]. The reasoning comes primarily from abstract set theory and from the study of groups of linear transformations acting on vector spaces. We give a simple example below that illustrates the Banach-Tarski theorem. EXAMPLEA.l

We will show that there exists a subset S c [O. 2 ) , in the real line, for which S IR. That is, S c [O,2) will be congruent by countable decomposition to the entire real line. The congruence mappings will be translations. The example begins with the proof in Example 3.1 that there exists a nonmeasurable subset of the line. There we defined an equivalence relation:

r

-

y

- y E $.

Note that each real number is equivalent modulo rational translation to numbers in the interval [ O , l ) . We use the Axiom of Choice to select an uncountable set C in [ O , 1 ) having the property that C consists of one element from each equivalence class in IR/ -. The set C is called a cross section of IR/ -. If we were still in Example 3.1, we would proceed to explain why the set C must be nonmeasurable. Instead, the example takes a surprising turn. Let U = Q n [O. 11, and let C, = C + q. Define

'

the disjoint union of the countably many translates of C by q E U . Thus S c [O, 2 ) . Let r:U+$ be a bijection between the two countable sets, U and xq =

0. Let

T(4) - g

for each q E U . Observe that

as claimed. 'The author learned the following example from the website of Professor Terence Tao at UCLA. This surprise ending for the famous example of a nonmeasurable set deserves to be better known. because it is so simple, compelling, and delightful.

228

THE BANACH-TARSKI THEOREM

This example shows with convincing simplicity an instance of a congruence, by countable decomposition, between two seemingly incongruous sets. It provides a compelling explanation of why it is necessary to check for measurability in analysis. It gives also a startling sense of the geometrical possibilities of nonmeasurable sets. The theorem of Banach and Tarski demonstrates that the tools of Lebesgue measure and integration, with all their strength, cannot measure all sets, even with firzite additivity. More striking is the capacity of nonmeasurable sets to be reconfigured in astounding ways, with geometrical perfection, losing nary a point. Thanks to Lebesgue and many other mathematicians, the understanding of measure and integration has been advanced in many ways that are invaluable to analysis. Yet the mysteries that stand are more profound than those that came before. This is a challenge and an invitation to the student to engage in the search to expand human knowledge. It affirms for us the grandeur of truth, the finiteness of ourselves, and the good fortune to be allowed a glimpse.

REFERENCES

1. S. Banach, Sur l’kquation fonctionnelle f(r + y) = f(r) + f ( y ) . Fiindamrnta Marhematicae, Tom 1, Warszawa, 1920.’ 2. S. Banach and A. Tarski, Sur la dicomposition des ensembles en parties respectivement congruentes. Fundamenta Mathematicae, Tom 6, Warszawa, 1924.’ 3. Lennart Carleson, On convergence and growth of partial sumas of Fourier series. Acra Mathematica, Vol. 116, 1966, pp. 135-157. 4. L. Corwin and F. P. Greenleaf, Representations ofNilpotent Lie Groups and Their Applications. Cambridge University Press, Cambridge, 1990. 5 . H. Dym and H. P. McKean, Fourier Series and Integrals. Academic Press, New York, 1972.

6. J. B. J. Fourier, Thkorie Analytique de la Chaleur. Firmin Didot, Paris, 1822. 7. B. Gelbaum and J. Olmsted, Counrerexamples in Analysis. Holden-Day, San Francisco, 1964. 8. C. Goffman, Real Functions. Rinehart and Company, New York, 1953. 9. C. Goffman and G. Pedrick, First Course in Functional Analysis. Prentice-Hall, Englewood Cliffs, NJ, 1965. ]This historic paper is available online from the Institute for Computational Mathematics at the University of Warsaw in Poland at http://matwbn.icm.edu.pl/.

Measure and Integration: A Concise Introduction to Real Analysis. By Leonard F. Richardson Copynght @ 2009 John Wiley & Sons, Inc.

229

230

REFERENCES

10. P. Halmos, Measure Theory. D. vdn Nostrand Company, New York, 1950.

1 1. G. Hamel, Eine basis aller zahlen und die unstetigen losungen des funktionalgleichung f(x + y) = f ( z ) f ( y ) . Mathematische Annalen, Vol. 60, 1905, pp. 459-462.

+

12. Kenneth Hoffman and Ray Kunze, Linear Algebra. Prentice-Hall, Englewood Cliffs, NJ, 1971. 13. P. Jordan and J. v. Neumann, On inner products in linear, metric spaces. Annals of Mathematics, Vol. 36, No. 3, 1935, pp. 719-723. 14. S. Kakutani, Concrete representation of abstract (M)-spaces (A characterization of the space of continuous functions). Annals ofMathernatics, 2nd Ser., Vol. 42, No. 4, pp. 1941,994-1024.

15. S. Kakutani, A proof of the uniqueness of Haar’s measure. Annals ofMathernatics, Vol. 49, 1948, pp. 225-226. 16. E. Kamke, Theory of Sets, translated by F. Bagemihl. Dover Publications, New York, 1950. 17. The MacTutor H i s t o ~ yof Mathematics, Archive of the University of St. Andrews, Fife, Scotland.’ 18. L. Nachbin, The Haar Integral. D. van Nostrand Company, New York, 1965. 19. L. Pukanszky, LeFons sur les Repre‘sentarions des Groupes. Dunod, Paris, 1967. 20. L. Richardson, Advanced Calculus: A n Introduction to Linear Analysis. John Wiley & Sons, 2008. 21, F. Riesz and B. Sz.-Nagy, Functional Analysis. Frederick Ungar Publishing Company, New York. 1955. 22. S. Saks, Theory ofthe Integral, 2nd ed., translated by L. C. Young. Hafner Publishing Company, New York. (First ed. Warsaw, 1937.’) 23. S. Saks, Integration in abstract metric spaces. Duke Mathematics Journal, Vol. 4, 1938, pp. 408-41 1. 24. G. E. Shilov and B. L. Gurevich, Integral, Measure and Derivative: A Unijied Approach, translated by R. A. Silverman. Prentice-Hall. Engleewood Cliffs, NJ, 1966. 25. S . Wagon, The Banach-Tarski Paradox. Cambridge University Press, Cambridge, 1986.

?This archive is at http://www-history.mcs.st-andrews.ac.uWhistory/index.html. 3Thishistoric book is available online from the Institute for Computational Mathematics at the University of Warsaw in Poland at http://matwbn.icm.edu.pl/.

INDEX

(I?,+), 196

(T,.), 203 1 A ( X ) , 61 1s. 5 A A B , 43 AC.21 B * , 171 D+, 135 D - , 135 D + . 135 D-, 135 E O . 54 Fo?35 Gg. 35 I o , 137 L l ( X . C ) , 100 L 1 ( X . R), 100 L1(X,U. p ) , 93 L2(T), 196 LP, 165 L*. 173 L* (X. U. p ) . 146 U,,, 220 Q N , 50 S N . 197 s,, 104

2.

226

$, 157

1, 40

Measure arid Integration: A Concise Introduction to Real Analysis. By Leonard F. Richardson Copyright @ 2009 John Wiley & Sons, Inc.

231

232

INDEX

f dp, 71. 76

f * g. 114

7-1, dp, 219 f dp, 73 5.y fdP9 78 A l p , 161 X < p. 156

f i I . 140 f < 1. 140

JA

5:

,s

P

> cp.

157 37 liin inf A,, 44 lim sup A,, 44 BV(1). 124 C P ( T ) , 199 cy (R).210 L , 78 L+,75 M , 156 s.95 S(IR),209 U@B, 107 U@B,107 2l x 23, 107 2-p-a.e.. 60 B(IR),36 B(W),50 3. 52 C, 33, 36 C(IR). 36 C(IRn), 50 ??(X), 11 R[a, b], 4. 5 6 , 61 60, 69 61. 72 a.e., 60 p*. 24 X

[XI,

155 p - , 155 p f . 156 I-(+.

z,

134 a-algebra, 13 a-field. 13 ~ ( 4 )81. v, 58, 158

1-4 155

c.,, 58, 85

4 208

E , 206 r?, 216 8. 208 ?, 203 101, 208 .S, 104 f * x,207

f?

f f f

-

g, 93 v g. 58 A

9. 58

f+. 78 f - , 78

I , 33. 36 11, 101 12, 183 .(A). 124 n(x). 124 p ( A ) , 124 p(x), 124 .(A). 124 ~ ( 5 )124 . x-section function. 105 absolutely continuous function, 140 bounded variation, 140 measure, 156 algebra, 1 1 -a, 13 almost everywhere. 60 %-p-almost everywhere, 60 Baire Category theorem, 46 function, 57 Banach space. 95 complex, 95 isomorphism. 175 real, 95 reflexive, 18 1 Banach-Tarski example, 227 paradox, 226 theorem, 226 Bessel’s inequality. 182 Borel function, 57 Borel field, 13 Borel measure regular. 185 signed regular, 185 Borel sets abstract, 13, 16, 24 closed sets, 35 generated by topology, 37, 5 I in IR,16 in R k , 16

INDEX

in Tychonoff cube, 17 in unit k-cube. 17 in unit interval. 16 in unit square, 16 not Fb,47 not Gs, 47 open sets, 35, 36, 51 bounded variation, 124 differentiability, 132 Cantor function, 141 Cantor set. 39. 141 CarathCodory outer measure, 21 Cauchy sequence, 4 3 normed linear space, 95 Cauchy-Schwarz inequality, 180 character, 197, 203 group, 203 of IR, 208 circle as multiplicative group, 203 as quotient group, 196 nonstandard, 203 complete normed linear space, 95 complex number imaginary part. 180 real part, 180 concave function, 81 continuous function absolutely, 140 measure absolutely, 156 convergence Fatou’s theorem, 9 1 in measure, 65, 100 Lebesgue Dominated, 84 monotone, 89 convex function, 81 supporting line, 81 convolution, 114. 207 countably additive measure, 20 set function, 79 counting measure. 20 cylinder set, 17 decreasing sequence, 13 dense subet of L z . 202 subset of L1, 94 density point, 148 derivative

lower. 135 one-sided. I35 under integral sign. 147 upper. 135 Dirichlet kernel, 198 dual space, 172 of L p . 175 Egoroff’s theorem, 62 elementary sets. 12 abstract. 24 in IRn, 50 in finite interval, 31 in unit square. 16 product measure, 103 epigraph. 81 equivalence class in L1, 93 essential sup-norm, 60, 167 supremum, 146, 173 essentially bounded, 146 exponential function trigonometric, 197 Fatou’s theorem. 9 1 field 0-, 13 elementary sets in IR. 12 Bore], 13 elementary sets in IRn. 50 generated by U 12. 13 finite intersection property. 33 floor function, 37 Fourier series. 197 transform eigenfunctions. 2 13 for L1(IR), 208 for L2(R), 214 Hermite functions. 2 I3 in Hilbert space, 181 inverse, 208 on circle. 197 Fourier transform for L1@) continuity, 208 Riemann-Lebesgue lemma, 208 Fubini’s theorem first form. 108 main form, 1 1 1

233

234

INDEX

function R*-valued. 58 %-measurable. 56 complex, 56 topological space valued. 56 %-simple, 61 special, 69 z-section. 105 indicator, 5 absolutely continuous, 140 bounded variation, 140 part. 163 Baire. 57 Borel. 57 Cantor. 141 carrier a-finite. 158 of finite measure, 72 complex valued, 100 concave, 81 continuous, 139 convex, 81 essentially bounded, 146 extended IR-valued measurable, 58 Hilbert space valued. 204 imaginary part, 100 indicator, 61 integrable, 78 Lebesgue integral, 78 measurable Borel equivalent, 62, 98 homomorphism of R,68, I 3 1 real part. 100 Schwartz. 209 dense in L2(R), 214 simple, 61 special, 69 singular, 140 part, 163 step, 95 dense in L1(R), 98 truncation. 74 uniformly continuous, 139 functional bounded, 171 continuous, 170 linear, 170 Fundamental theorem Lebesgue integral, 129 Holder's inequality, 167 Hahn Decomposition theorem, 154 Heisenberg

Commutation Relation, 222 group. 223 Uncertainty Principle. 222 Hermitian inner product. 179 space, 179 Hilbert space, 179 direct integral. 219 direct sum. 204 orthonormal basis, 182 separable, 182 Hopf Extension Theorem, 24 uniqueness. 28 increasing sequence, I3 indefinite integral, 127 index set, 181 indicator function, 5 inequality Jensen's. 82 inherited measure space, 29 inner Lebesgue measure, 36 product Hermitian, 179 integrable locally. 131 integral additive on domains, 72 as set function. 71. 73. 76 complex valued, 100 counting measure. 81 Hilbert space valued. 204 indefinite, 127, 129 Lebesgue reflection invariance, 8 0 translation invariance. 80 linear functional, 70 on c+,75 73 on 61. sign derivative under, 147 special simple function, 7 0 irreducible. 2 I9 Jensen's inequality, 82 for real numbers, 166 Jordan content, 52 measure, 52 inner, 52 outer. 52 null set, 53

INDEX

Jordan Decomposition theorem, 156 Jordan measurable, 52 kernel Dirichlet, 198 LDC. 84, 212 Lebesgue Decomposition theorem, 161 Dominated Convergence. 84 measure outer. 36 theorem, 118. 132 linear functional. 170 bounded, 171 continuous, 170 positive, 187 linear space normed complete, 95 lower sum

on IR.4 Lusin’s theorem, 66 measurable function, 56 homomorphism of IR. 68. 131 set, 21 space, 38 measure absolutely continuous, 156 approximately finite, I9 Caratheodory outer, 2 I regular, 27 countably additive on 2l. 20, 24, 27 counting, 20 finite. 19 -u,20 finitely additive, 19 infinite. 19 Jordan, 52 Lebesgue, 33, 36. SO complete, 38 essential uniqueness, 115 in IR.36. 50 inner, 36 on [ - N , N ) , 33 outer, 36 reflection invariance. 52 translation invariance. 37. 51 norm of, 155 probability, 82 product

in IR2. 107 on E, 104 signed, 151. 152 singular. 161 space. 38 complete, 38 measure space. 38 completion. 41 minimal, 41 extension, 41 inherited, 29 metric. 43 metric space. 43 Minkowski’s inequality. 167 momentum operator. 222 monotone class, 13 generated by 2l. 13 monotone convergence theorem, 89 nonstandard circle, 203 norm, 93 L’. 93 LI’. 166 in a vector space. 93 of functional, 172 total variation, 155 null set. 38 orthogonal complement. I8 1 orthogonal projection. 2 17 orthonormal basis Hilbert space, 182 outer Lebesgue measure, 36 measure, 36 Caratheodory. 2 I. 25 Lebesgue. 36 Parallelogram Law. 184 Parseval’s Identity for L*(IR). 215 separable Hilbert space. 184 partition, 4. 124 mesh. 4 Plancherel identity. 182. 201 Pointwise Convergence Lemma. 96 position operator, 22 I power set. 1 I premeasurable space. 30 premeasure space, 29 probability measure. 82 space. 82

235

236

INDEX

Radon-Nikodym derivative, I57 theorem, 157 real numbers extended. 18 rectangular set. 103 reflection invariance, 52 regular Borel measure, 185 signed Borel measure. 185 representation theorem LP-LP duality, 175 Riesz-Markov-Saks-Kakutani, 186 Riemann -Lebesgue lemma. 98, 199, 208 integral, 4. 81. 118 deficiencies. 3 lower, 118 upper, I 18 rotation, 220 scalar product Hermitian. 179 section x-,104 y-. 104 semimetric, 43 separable Hilbert space, 182 separable Hilbert space L2 ( R ) , 183 sequence absolutely summable. I01 Cauchy. 43 normed linear space, 95 set Cantor, 39, 141 category first. 46 second, 46 convex, 81 index, 181 interior, 137 Lebesgue not Jordan, 54 measurable, 21 nonmeasurable, 42 in any P.l(P) > 0, 49 null, 38 set function countably additive, 79, 151, 152 sets Fo,35

Gg, 35 algebra of, I 1 Borel in R, 36 , in R r L50 congruent, 226 by countable decomposition, 226 by finite decomposition, 226 field of, 11 Lebesgue measurable, 33 limit inferior, 44 limit superior. 44 measurable, 21. 28 between F, and GJ. 35 between open and closed. 35 density point of. 148 in R, 36 in R", 50 Lebesgue. 33 signed Borel measure regular. 185 signed measure, 152 space normed vector. 93 dual. 172 measurable, 38. 55 measure, 38. 55 inherited, 29 metric, 43 complete. 43 semi-, 43 premeasurable, 30 premeasure, 29 inherited, 29 probability, 82 spectrum, 206, 216 state function. 221 Steinhaus theorem. 48, i 15 congruent decomposition. 1-19 step function, 95 sup-norm, 72 essential, 167 supporting line convex function. 8 I symmetric difference. 43 Tonelli's theorem, I12 transform Fourier. 98 Fourier-Stieltjes, 193 translation invariance. 37, 5 I triangle inequality. 43 complex space. 183 norms. 93

INDEX

sets. 43 Tychonoff cube, 17 Uncertainty Principie, 222 upper sum on IR. 4 variation, 123 bounded, 124 negative, 124 positive. I24 total, 155 Vitali covering theorem, 132 property. 132

237