Problems in Mathematical Analysis III: Integration [1 ed.] 0821832980, 9780821832981

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Table of contents :
Cover
Title
Copyright
Contents
Preface
Part 1. Problems
Chapter 1. The Riemann-Stieltjes Integral
§1.1. Properties of the Riemann-Stieltjes Integral
§1.2. Functions of Bounded Variation
§1.3. Further Properties of the Riemann-Stieltjes Integral
§1.4. Proper Integrals
§1.5. Improper Integrals
§1.6. Integral Inequalities
§1.7. Jordan Measure
Chapter 2. The Lebesgue Integral
§2.1. Lebesgue Measure on the Real Line
§2.2. Lebesgue Measurable Functions
§2.3. Lebesgue Integration
§2.4. Absolute Continuity, Differentiation and Integration
§2.5. Fourier Series
Part 2. Solutions
Chapter 1. The Riemann-Stieltjes Integral
§1.1. Properties of the Riemann-Stieltjes Integral
§1.2. Functions of Bounded Variation
§1.3. Further Properties of the Riemann-Stieltjes Integral
§1.4. Proper Integrals
§1.5. Improper Integrals
§1.6. Integral Inequalities
§1.7. Jordan Measure
Chapter 2. The Lebesgue Integral
§2.1. Lebesgue Measure on the Real Line
§2.2. Lebesgue Measurable Functions
§2.3. Lebesgue Integration
§2.4. Absolute Continuity, Differentiation and Integration
§2.5. Fourier Series
Bibliography -Books
Index
A
B
C
D
E
F
H
I
J
L
M
O
P
R
S
T
U
V
W
Y
Back Cover
Recommend Papers

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Copyright 2003 American Mathematical Society. Duplication prohibited. Please report unauth Thank You!

http://dx.doi.org/10.1090/stml/021

Problems in Mathematical Analysis HI Integration

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STUDENT MATHEMATICAL LIBRARY Volume 21

Problems in Mathematical Analysis III Integration W. J. Kaczor M.T. Nowak

#AMS

AMERICAN MATHEMATICA L SOCIET Y

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Editorial Boar d David Bressoud , Chai r Danie

l L . GorofT Car

l Pomeranc e

2000 Mathematics Subject Classification. Primar y 00A07 , 26A42 ; Secondary 26A45 , 26A46 , 26D1 5 , 28A1 2 . For additiona l informatio n an d updates o n this book , visi t www.ams.org/bookpages/stml-21 Library o f Congres s Cataloging-in-Publicatio n D a t a Kaczor, W . J . (Wieslaw a J.) , 1 949 [Zadania z analizy matematycznej . English ] Problems i n mathematica l analysis . I . Rea l numbers , sequence s an d serie s / W. J . Kaczor , M . T. Nowak . p. cm . — (Studen t mathematica l library , ISS N 1 520-91 2 1 ; v. 4) Includes bibliographica l references . ISBN 0-821 8-2050- 8 (softcove r ; alk. paper ) 1. Mathematica l analysis . I . Nowak , M . T . (Mari a T.) , 1 951 - II . Title . III. Series . QA300K32513 200 0 515'.076— dc2199-08703

9

Copying an d reprinting . Individua l reader s o f thi s publication , an d nonprofi t libraries actin g fo r them , ar e permitte d t o mak e fai r us e of th e material , suc h a s to copy a chapte r fo r us e in teachin g o r research . Permissio n i s grante d t o quot e brie f passages fro m thi s publicatio n i n reviews, provide d th e customary acknowledgmen t of the sourc e i s given. Republication, systemati c copying , o r multiple reproductio n o f any materia l i n this publication i s permitted onl y unde r licens e fro m th e American Mathematica l Society . Requests fo r suc h permissio n shoul d b e addresse d t o th e Acquisition s Department , American Mathematica l Society , 20 1 Charles Street , Providence , Rhod e Islan d 02904 2294, USA . Requests ca n also be made b y e-mail t o [email protected] . © 200 3 b y the American Mathematica l Society . Al l rights reserved . The America n Mathematica l Societ y retain s al l right s except thos e grante d t o the United State s Government . Printed i n the United State s o f America . @ Th e paper use d i n this boo k i s acid-free an d fall s withi n th e guideline s established t o ensure permanenc e an d durability . Visit th e AMS home pag e a t http://www.ams.org / 10 9 8 7 6 5 4 3 2 1 0

8 07 06 05 04 0 3

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Contents

Preface vi

i

Part 1 . Problem s Chapter 1 . Th e Riemann-Stieltje s Integra l 3 §1.1. Propertie s o f th e Riemann-Stieltje s Integra l 3 §1.2. Function s1 o f Bounde d Variatio n

0

§1.3. Furthe r Propertie s o f th e Riemann-Stieltje s Integra 1l

5

§1.4. Prope r Integral s 2 1 §1.5. Imprope r Integral s 2

8

§1.6. Integra l Inequalitie s 4

2

§1.7. Jorda n Measur e 5

2

Chapter 2 . Th e Lebesgu e Integra l 5

9

§2.1. Lebesgu e Measur e o n th e Rea l Lin e 5

9

§2.2. Lebesgu e Measurabl e Function s 6

6

§2.3. Lebesgu e Integratio n 7 1 §2.4. Absolut e Continuity , Differentiatio n an d Integratio n 7

9

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Contents

VI

§2.5. Fourie r Serie s 8

4

Part 2 . Solution s Chapter 1 . Th e Riemann-Stieltje s Integra l 9

7

§1.1. Propertie s o f th e Riemann-Stieltje s Integra l 9

7

§1.2. Function s 1 o1 f Bounde d Variatio n

4

§1.3. Furthe r Propertie s o f the Riemann-Stieltje s Integra1l 2

6

§1.4. Prope r Integral s 4

3

1 §1.5. Imprope r Integral s 6

4

§1.6. Integra l Inequalitie s 20

7

§1.7. Jorda n Measur e 22

8

Chapter 2 . Th e Lebesgu e Integra l 24

7

§2.1. Lebesgu e Measur e o n th e Rea l Lin e 24

7

§2.2. Lebesgu e Measurabl e Function s 26

8

§2.3. Lebesgu e Integratio n 28 1 §2.4. Absolut e Continuity , Differentiatio n an d Integratio n 29

6

§2.5. Fourie r Serie s 3

6

Bibliography - Book s 35 1 Index 35

5

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Preface

This i s a seque l t o ou r book s Problems in Mathematical Analysis I, II (Volume s 4 an d 1 2 i n th e Studen t Mathematica l Librar y series) . The boo k deal s with th e Riemann-Stieltje s integra l an d th e Lebesgu e integral fo r rea l function s o f one rea l variable . Th e boo k i s organize d in a wa y simila r t o tha t o f the firs t tw o volumes , tha t is , i t i s divide d into tw o parts : problem s an d thei r solutions . Eac h sectio n start s with a numbe r o f problem s tha t ar e moderat e i n difficulty , bu t som e of th e problem s ar e actuall y theorems . Thu s i t i s no t a typica l prob lem book , bu t rathe r a supplemen t t o undergraduat e an d graduat e textbooks i n mathematica l analysis . W e hop e tha t thi s boo k wil l b e of interes t t o undergraduat e students , graduat e students , instructor s and researche s i n mathematical analysi s an d it s applications. W e also hope tha t i t wil l b e suitabl e fo r independen t study . The first chapte r of the book is devoted to Riemann an d Riemann Stieltjes integrals . I n Sectio n 1 . 1 w e conside r th e Riemann-Stieltje s integral wit h respec t t o monotoni c functions , an d i n Sectio n 1 . 3 w e turn t o integratio n wit h respec t t o function s o f bounde d variation . In Sectio n 1 . 6 w e collec t famou s an d no t s o famou s integra l inequal ities. Amon g others , on e ca n fin d OpiaP s inequalit y an d Steffensen' s inequality. W e clos e th e chapte r wit h th e sectio n entitle d "Jorda n measure". Th e Jorda n measure , als o calle d conten t b y som e authors ,

vn

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Vlll

Preface

is no t a measur e i n th e usua l sens e becaus e i t i s no t coun t ably addi tive. However , i t i s closely connecte d wit h th e Rieman n integral , an d we hope that thi s section will give the student a deeper understandin g of the idea s underlyin g th e calculus . Chapter 2 deals with the Lebesgu e measur e an d integration . Sec tion 2. 3 present s man y problem s connecte d wit h convergenc e theo rems tha t permi t th e interchang e o f limi t an d integral ; LP spaces o n finite interval s ar e als o considere d here . I n th e nex t section , absolut e continuity an d the relation between differentiation an d integration ar e discussed. W e present a proo f o f th e theore m o f Banac h an d Zareck i which state s tha t a function / i s absolutely continuou s o n a finite in terval [a , b] i f and onl y i f it i s continuous an d o f bounded variatio n o n [a, b], an d map s set s o f measur e zer o int o set s o f measur e zero . Fur ther, th e concep t o f approximate continuit y i s introduced. I t i s worth noting her e that ther e i s a certain analog y betwee n tw o relationships : the relationshi p betwee n Rieman n integrabilit y an d continuity , o n the on e hand , an d th e relationshi p betwee n approximat e continuit y and Lebesgu e integrability , o n th e othe r hand . Namely , a bounde d function o n [a , b] i s Rieman n integrabl e i f an d onl y i f i t i s almost ev erywhere continuous ; an d similarly , a bounde d functio n o n [a , b] is measurable, an d s o Lebesgu e integrable , i f an d onl y i f i t i s almos t everywhere approximatel y continuous . Th e las t sectio n i s devoted t o the Fourie r series . Give n th e existenc e o f extensiv e literatur e o n th e subject, e.g. , th e book s b y A . Zygmun d "Trigonometri c Series" , b y N. K . Bar i " A Treatis e o n Trigonometri c Series" , an d b y R . E . Ed wards "Fourie r Series" , w e foun d i t difficul t t o decid e wha t materia l to includ e i n a boo k whic h i s primaril y addresse d t o undergraduat e students. Consequently , w e hav e mainl y concentrate d o n Fourie r co efficients o f function s fro m variou s classe s an d o n basi c theorem s fo r convergence o f Fourie r series . All the notatio n an d definition s use d i n this volume ar e standard . One ca n find the m i n the textbook s [27 ] and [28] , which als o provid e the reade r wit h th e sufficien t theoretica l background . However , t o avoid ambiguit y an d t o mak e the boo k self-containe d w e start almos t every sectio n wit h a n introductor y paragrap h containin g basi c defi nitions an d theorem s use d i n th e section . Ou r referenc e convention s

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Preface

IX

are bes t explaine d b y th e followin g examples : 1 .2.1 3 or I , 1 .2.1 3 o r II, 1 .2.1 3 , whic h denot e th e numbe r o f th e proble m i n thi s volume , in Volum e I o r i n Volum e II , respectively . W e als o us e notatio n an d terminology give n i n th e first tw o volumes . Many problem s hav e bee n borrowe d freel y fro m proble m section s of journals lik e the America n Mathematica l Monthl y an d Mathemat ics Today (Russian) , an d fro m variou s textbooks an d proble m books ; of thos e onl y book s ar e liste d i n th e bibliography . W e woul d lik e t o add tha t man y problem s i n Sectio n 1 . 5 com e fro m th e boo k o f Ficht enholz [1 0 ] an d Sectio n 1 . 7 i s influence d b y th e boo k o f Rogosinsk i [26]. Regrettably , i t wa s beyon d ou r scop e t o trac e al l th e origina l sources, an d w e offer ou r sincer e apologies if we have overlooked som e contributions. Finally, w e woul d lik e t o than k severa l peopl e fro m th e Depart ment o f Mathematics o f Maria Curie-Sklodowsk a Universit y t o who m we are indebted . Specia l mentio n shoul d b e mad e o f Tadeusz Kuczu mow an d Witol d Rzymowsk i fo r suggestion s o f severa l problem s an d solutions, an d o f Stanisla w Pru s fo r hi s counselin g an d Te X support . Words o f gratitud e g o t o Richar d J . Libera , Universit y o f Delaware , for hi s generou s hel p wit h Englis h an d th e presentatio n o f th e ma terial. W e ar e ver y gratefu l t o Jadwig a Zygmun t fro m th e Catholi c University o f Lublin , wh o ha s draw n al l th e figure s an d helpe d u s with incorporatin g the m int o th e text . W e than k ou r student s wh o helped u s i n th e lon g an d tediou s proces s o f proofreading . Specia l thanks g o t o Pawe l Sobolewsk i an d Przemysla w Widelski , wh o hav e read th e manuscrip t wit h muc h car e and thought , an d provide d man y useful suggestions . Withou t thei r assistanc e som e errors , no t onl y ty pographical, coul d have passed unnoticed . However , we do accept ful l responsibility fo r an y mistake s o r blunder s tha t remain . W e woul d like t o tak e thi s opportunit y t o than k th e staf f a t th e AM S fo r thei r long-lasting cooperation , patienc e an d encouragement . W. J . Kaczor , M . T . Nowa k

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Part 1

Problems

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Chapter 1

The Riemann-Stieltje s Integral

1.1. Propertie s o f th e Riemann-Stieltje s Integra l We star t wit h som e basi c notations , definition s an d theorems . B y a partition P o f a close d interva l [a , b] we mea n a finite se t o f point s xo, xi,..., xn suc h tha t a = XQ < x\ < .. . < x n-\ < The numbe r n(P) = maxjx ^ — xi-\ : raes/i of P.

x n = b.

i = 1 , 2 , . .. ,n} i s calle d th e

For a functio n a monotonicall y increasin g o n [a , b] w e writ e A ^ = a(xi) - a(xi-i). If / i s a real function bounde d o n [a , 6], we define th e uppe r an d lowe r Darboux sum s o f / wit h respec t t o a an d relativ e t o P , respectively , by nn

U(P,f,a) =

Y,MiAa t, L(P,f,a)

=

^m^Aa, ,

where Mi = su

p /(#)

, ^

i = in

f /(#)

• 3

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4

Problems. 1 : Th e Riemann-Stieltje s Integra l

We als o pu t pb rb

/ fda = mfU(P if,a), /

fda = supL(P , f,a),

J aJ

a

where th e infimu m an d th e supremu m ar e taken ove r al l partition s P of [a, 6], and call them, respectively, the upper an d the lower Riemann Stieltjes integral . I f th e uppe r an d th e lowe r Riemann-Stieltje s inte grals are equal, we denote the common valu e by / fda an d cal l it th e Riemann-Stieltjes integra l o f / wit h respec t t o a ove r [a , b]. I n thi s case w e sa y tha t / i s integrabl e wit h respec t t o a , i n th e Rieman n sense, an d w e writ e / G 1Z(a). I n th e specia l cas e o f a(x) = x w e get th e Rieman n integral . I n thi s cas e th e uppe r (lower ) Darbou x sum correspondin g t o a partitio n P , an d th e uppe r (lower ) Rieman n integral ar e denoted , respectively , b y U(P,f) ( L ( P , / ) ) , an d f (fafdx) .

afdx

The Rieman n integra l o f / ove r [a , b] i s denoted b y j a fdx.

Moreover, correspondin g t o ever y partitio n P o f [a , b] w e choos e points t i , t 2 , . . . , t n suc h tha t Xi-\ < t{ < Xi, i = 1 ,2 , . . . , n , an d consider th e su m n

5(P,/,a) = 53/(ti)Aai. 2 =1

We say tha t lim S(PJ,a)

=

A

if, fo r ever y e > 0 , ther e i s S > 0 suc h tha t /i(P ) < S implie s tha t |5(P, /, a) — A\ < e fo r al l admissibl e choices o f U. I n th e cas e whe n a(x) — x w e se t

5(P,/) = £/(*i)(x i -x < _ 1 ). i=l

Throughout thi s section , / i s always assume d t o b e bounde d an d a monotonicall y increasin g o n [a , b]. I n th e solution s w e will often us e the followin g theorem s (see , e.g. , Rudi n [28]) . Theorem 1 . / G 71(a) on [a , b] if and only if for every e > 0 there exists a partition P such that

U(PJ,a)-L(PJ,a) 0 an d (x ifx G [ - o , o ] n Q , [0 i f x G [ - a , a ] \ Q . Find th e uppe r an d lowe r Rieman n integral s o f / ove r [—a , a]. 1.1.5. Sho w tha t th e so-calle d Rieman n functio n 0i f{x) = {l/q i

f x i s irrational o r x = 0 , f x = p/q, p G Z , g r G N , an d p, g are co-prime ,

is Riemann integrabl e o n ever y interva l [a , b]. 1.1.6. Le t / : [0,1] - + R b e define d b y settin g

[0 otherwise . Show tha t J Q f(x)dx = 0. 1.1.7. Sho w tha t / : [0,1] - > R define d b y

\x ~ ix] otherwis

e

is Riemann integrabl e o n [0,1 ] .

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6

Problems. 1 : Th e Riemann-Stieltje s Integra l

1.1.8. Defin e JO if * G [-1,0], / /(x) = < an d a(x \ l i f x G ( 0 , l ] , \l Show tha t / G 7£(a ) althoug h li m S(P,

O if * G [-1,0), )= < iixe [0, 1 ] . / , a) doe s no t exist .

1.1.9. Sho w tha t i f / an d a hav e a commo n poin t o f discontinuity i n fa, 61 , then li m S(P, f.a) doe s no t exist . LJ

'M

(P)-o v

)

1.1.10. Prov e tha t i f li m S(P,

/ , a) exists , the n / G 1 1 (a) o n [a , 6]

/x(P)-0

and lim 5(P ; , /, a) = / / d a .

M(P)-O V

J

a

Show als o tha t fo r ever y / continuou s o n [a , 6], th e abov e equalit y holds. 1.1.11. Sho w tha t i f / i s bounded an d a i s continuous o n [a , 6], the n / G 1 Z(a) i f an d onl y i f li m S(P, / , a) exists . MP)-o 1.1.12. Le t (c i f a < x < x*, a(x) = < [d i f x * < x < 6 , where c < d an d c < a(x*) < d. Sho w tha t i f / i s bounde d o n [a , 6] and suc h tha t a t leas t on e o f th e function s / o r a i s continuous fro m the lef t a t x * an d th e othe r i s continuou s fro m th e righ t a t x*, the n / G 1 1 (a) an d C

f(x)da(x) =

f(x*)(d-c).

Ja

1.1.13. Suppos e that / i s continuous o n [a , 6] and a i s a step function that i s constant o n th e subinterval s (a , ci), (ci, C2),..., (c m , 6), wher e a < c\ < C2 < • - • < c m < 6. Sho w tha t b ™>

/ f(x)da(x) =

/(o)(a(a+ ) - a(a)) + £ /(c

fc )(a(c+)

- a(c fe"))

fc=i

+ /(6)(a(6)-a(fe")) .

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1.1. Propertie s o f the Riemann-Stieltjes Integra l 7 1.1.14. Usin g Rieman n integral s o f suitabl y chose n functions , find the followin g limits : (a) li m ( + + •• • + — ), v; n-o o \n + 1 n + 2 3nJ ini n2 3 + -" + ( b ) Jn-^oo „y n ( ^ r3 T+-l^3 +n ^3 -+ T2 ^ n

(c) h m ^-

j,

k

3

- f n3 / '

> 0,

(d) li m - ij/( n + l)( n + 2)---( n + n), n—>oo 77 , / 77

, 77

, 77

,

(e) li m si n +i2 i 2 n sin H2 + 2 2 n h + ol/n 0. /

1.1.17. Fo r k > 0, calculat e fc fc l i m / l + 3 + -- - + ( 2 n - l )

n—>oo \ 7 7 /

fc

^

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Problems. 1 : Th e Riemann-Stieltje s Integra l

8

1.1.18. Suppos e tha t / i s twic e differentiabl e o n [0,1 ] an d / " i s bounded an d Rieman n integrable . Sho w tha t

^y(£mdx-±±f

2i-i\\ _ r ( i ) - r ( o ^ 2n 2

)

4

1.1.19. Fo r n G N , defin e

1 1

J

_

and 2

2

2n + 1 2

n+3 4

n- 1

Show tha t lim [7 n = li m V n — I n 2. n—>oo n—

->oo

Moreover, usin g th e result s state d i n 1 .1 .1 6 and 1 .1 .1 8 , sho w tha t lim n(In 2 — U n) — - an n-^oo 4

d li

n—>o

m n 2 (ln2 — V n) — —. o 3

2

1.1.20. Sho w tha t i f / i s Rieman n integrabl e ove r [a , 6], the n / ca n be change d a t a finit e numbe r o f point s withou t affectin g eithe r th e integrability o f / o r th e valu e o f it s integral . 1.1.21. Sho w tha t i f / i s monotoni c an d a i s continuou s o n [a , 6], then / G 71(a). 1.1.22. Prov e tha t i f / G 71 (a) an d a i s neither continuou s fro m th e left no r fro m th e righ t a t a point i n [a , 6], then / i s continuous a t thi s point. 1.1.23. Le t / b e Rieman n integrabl e an d a continuou s o n [a , b]. I f a i s differentiabl e o n [a , b] except fo r finitel y man y point s an d a' i s Riemann integrable , the n / G IZ(a) an d pb pb

/ f(x)da(x) =

Jo..

/ f(x)a'(x)dx. Ja

1.1.24. Le t / b e Rieman n integrabl e an d a b e continuou s o n [a , b] except fo r finitel y man y points . I f a i s differentiabl e o n [a , b] except

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1.1. P r o p e r t i e s o f t h e Riemann-Stieltje s Integra l 9 for finitely man y point s an d a' i s Riemann integrable , the n / G 7Z(a) and pb pb

/ f(x)da{x)= f{x)a'{x)dx J a

+

f{a){a{a

+

)-a{a))

J a m

+ £ f(c

k)(a(4)

-

a(c~)) + f(b)(a(b) - a(b~)),

k=l

where c^ , k = 1 , 2 , . . ., m, ar e point s o f discontinuit y o f a i n (a , b). 1.1.25. Calculat e j_ 2x2da{x), wher

e

x+ 2 i

f -2 a , an d pu t V ( / ; a , o o ) = li m V(f;a,b). b—>oo

Show tha t i f V(f; a , 00) < 00 , the n th e finite limi t li m f(x) exists . x—*oo

Does th e opposit e implicatio n hold ? 1.2.15. Fo r / define d o n [a , b] an d a partitio n P — {xo,x'i,.. . , x n } of [a , 6], w e for m th e su m

vup)=x;i/(si)-/(zi-i)iProve tha t i f / i s continuou s o n [a , 6], the n lim V ( / , P ) = V(/:a,6) , that is , fo r an y s > 0 there exist s 6 > 0 such tha t //(P ) < < 5 implie s V(f;a.b)~V(f,P) m > 0 , x G [a , 6]. Sho w t h a t ther e ar e tw o monotonicall y increasin g functions g an d / i suc h t h a t

/?,(x)

1.2.19. Comput e th e positiv e an d negativ e variatio n function s o f (a) f(x)=^-\x\, a : G [ - l . l ] (b) f(x)

=

cosa: , x

(c) / ( ! • ) = J - M . . r

,

€ [0.2TT] ,

e [0.3] .

1.2.20. Assum e t h a t / i s o f bounde d variatio n o n [a , b]. Prove t h a t i f / i s continuou s fro m th e righ t (left ) a t TQ , the n Vf i s als o continuou s from th e righ t (left ) a t TQ. 1 . 2 . 2 1 . Sho w t h a t th e se t o f point s o f discontinuit y o f a functio n / o f bounde d variatio n o n [a J)] i s a t mos t countable . Moreover , i f

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14

P r o b l e m s . 1 : T h e Riemann-Stieltje s Integra l

{xn} i s the sequenc e o f points o f discontinuity o f / , the n th e functio n g(x) = f(x) — s(x), wher e s(a) = 0 an d s(x) = f(a+) - f(a) + £ (/(*+

) - f(x~)) + f(x) - / ( * " )

Xn/ also satisfies th e Lipschitz conditio n with the same Lipschitz constant . 1.2.24. Prov e tha t i f / i s o f bounde d variatio n o n [a , b] and enjoy s the intermediat e valu e property , the n / i s continuous. Conclud e tha t if / ' i s o f bounde d variatio n o n [a , 6], the n f i s continuous . 1.2.25. Prov e tha t i f / i s continuously differentiat e o n [a , 6], the n X

«/(*)= [

\f'(t)\dt.

Ja

1.2.26. Sho w tha t i f / i s continuous an d a monotonicall y increasin g on [a , 6], the n th e functio n F(x) = / f(t)da(t),

[a , b],

xe

./a

is o f bounde d variatio n o n [a , 6]. 1.2.27. I f / O ) = li m f n(x) fo r x G [a, b], the n n—->oo

V(f;a,b)< li

m V(/„;a,b) . n—• oo oo o

1.2.28. Suppos e tha t th e serie s ^T

a

o

n a n d Yl b n ar e absolutel y con -

n=l n=

l

vergent, an d le t {x n} b e a sequenc e o f distinc t point s i n (0,1 ) . Prov e that th e functio n / define d b y

/(0)=0, f(x)=

Yl

a

- + J2

b

^ fo

r

*e(0,l ]

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1.3. Furthe r Propertie s .. .

15

is continuou s a t ever y x ^ x n , n G N , an d f(xn) -

f(x~) =

a n , f(x+)

Prove als o tha t

- f(x n) =

b n.

oo

V(f;0,l) = Y,(K\ + K\). n=l

1.3. Furthe r Propertie s o f th e Riemann-Stieltje s Integral In this section w e consider Riemann-Stieltje s integral s wit h respec t t o functions o f bounded variation . I f a i s a function o f bounded variatio n on [a , 6], and i f a = p — q7 where p and q are monotonicall y increasing , then rb pb

rb

/ f(x)da(x) =

/ f{x)dp{x) - / f(x)dq(x),

Ja Ja

Ja

provided tha t / G Ti(p) an d / G l^{q) (se e th e definitio n i n Sectio n 1.1). Thi s definitio n doe s no t depen d o n a decompositio n o f a int o a difference o f tw o increasin g functions . T h e o r e m 1 . If functions f and a are of bounded variation on [a , b] and one of them is continuous, then f(b)a(b) - f(a)a(a) -

j f(x)da(x) =

f a(x)df(x).

The abov e formul a i s calle d th e partial integration formula. T h e o r e m 2 . Suppose f and Lp are continuous on [a , b] and ip is strictly increasing on [a , b]. If ip is the inverse function of (p, then / f(x)dx

=

/ f{rl>{y))dil>(y).

Ja J

(f(a)

The formula i n Theorem 2 is called the change of variable formula. T h e o r e m 3 . Suppose that either f is continuous and a is of bounded variation on [a,b], or f and a are of bounded variation on [a , b] and a is continuous. Then

I

b|

f(x)da(x)\
0, ^ c

n

< oc , an d defin e

n=\ oo Q ;r

C

( )= ^

np{x-Xn),

where th e functio n p is given b y 0i fx

< 0,

1i f x

> 0.

Prove tha t i f / i s continuou s o n [0,1 ] , the n DC

fda = ] P c

nf(xn

n=l

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1.3. Furthe r Propertie s .. .

17

1.3.5. Suppos e tha t a i s a continuou s functio n o f bounde d variatio n on [a , b] suc h tha t fo r ever y / continuou s o n [a , 6], rb

/

0.

f(x)da(x) =

J a

Show tha t a i s constan t o n [a , 6]. 1.3.6. Le t a b e monotonicall y increasin g o n [0,7r ] an d suc h tha t / sin

xda(x) = a(7r ) — a(0) .

Show tha t Ja(0) i

f XG[0,TT/2)

I CK(TT ) i f x

,

£ (7r/2,7r] .

1.3.7. Fin d a functio n a monotonicall y increasin g o n [0,1 ] an d suc h that

[f{x)Mx) = m±m for ever y / continuou s o n [0,1 ] . 1.3.8. Fin d a functio n / continuou s o n [a , b] an d suc h tha t rb

f(x)da(x) =

a(b) — a (a)

for ever y a monotonicall y increasin g o n [a , b]. 1.3.9. Assum e tha t a i s of bounde d variatio n o n [a , b] an d th e func tions / n , n = 1 ,2,... , ar e Riemann-Stieltje s integrabl e wit h respec t to a ove r [a , b]. Prove tha t i f {f n} converge s uniforml y o n [a , b] t o / , then / i s Riemann-Stieltje s integrabl e an d rb

rb

I f(x)da(x) =

li m / f

n(x)da(x).

1.3.10. Calculat e

f1 nx{\ - x

lim / o

l n

) dx.

n-o c 7Q

1.3.11. Fo r a o f bounde d variatio n o n [0,1 ] , find lim / x

n

da(x).

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P r o b l e m s . 1 : T h e Riemann-Stieltje s Integra l

18

1.3.12. Suppos e tha t {a n} i s a sequenc e o f function s whos e tota l variations ar e uniforml y bounde d o n [a , 6], that is , there i s a positiv e M suc h that V(a n; a , b) < M fo r al l n. Prov e that i f {a n} i s pointwise convergent t o a o n [a , 6], the n fo r ever y / continuou s o n [a , 6], lim / f(x)da n(x) = / f(x)da(x). ^°° J a J a 1.3.13. Suppos e tha t {a n} i s a sequenc e o f function s whos e tota l variations ar e uniformly bounde d o n [a , 6], and tha t {a n} i s pointwise convergent t o a o n [a , 6]. Suppos e als o tha t {fn} i s a sequenc e o f continuous function s uniforml y convergen t o n [a,b] t o / . Prov e tha t n

rb

lim / f

rb

n(x)dan(x) =

«/ a J

/ f(x)da(x). a

1.3.14. Prov e th e followin g Helly selection theorem. Le t {a n} b e a sequence o f function s define d o n [a,b] such tha t |a n (a)| < M an d V(an; a,b) < M fo r n G N . Then {a n} contain s a subsequenc e {a nk} convergent t o a functio n a o f bounde d variatio n o n [a , 6], an d fo r every continuou s functio n / , rb

rb

lim / f(x)da nk(x) = / /(x)da(x) . k -^°°Ja J a 1.3.15. Prov e th e followin g theorem of Helly whic h generalize s th e result i n 1 .3.1 2 . Le t / b e continuou s an d a o f bounde d variatio n on [a , b]. I f th e sequenc e {a n} o f function s o f uniforml y bounde d variation converge s t o a o n a se t A dens e i n [a , b] and suc h tha t a, b G A, the n rb

lim / f(x)da

rb

n(x)

=

/ f(x)da(x).

n—»oo

1.3.16. Prov e th e second mean value theorem. Suppos e / i s mono tonic an d a i s continuou s an d o f bounde d variatio n o n [a , b]. Then there i s a poin t c G [a, 6] such tha t /»6

/»c

rb

/ /(ar)da(a: ) = / ( a ) / da(x) + f(b) / da(x) J a

Ja

Jc

= /(a)(a(c ) - a(a) ) + /(6)(a(6 ) - a{c)). 1.3.17. Prov e th e followin g Bonnet forms of the second mean value theorem .

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1.3. Furthe r Propertie s .. .

19

(a) I f / i s a positiv e increasin g functio n o n [a , b] an d a i s a con tinuous functio n o f bounde d variatio n o n [a , 6], the n ther e i s a poin t c G [a , b] suc h tha t b rb

f(b) / da(x) = f(b)(a(b) - a(c)) .

f(x)da(x) =

(b) I f / i s a positiv e decreasin g functio n o n [a , b] an d a i s a con tinuous functio n o f bounde d variatio n o n [a , b], the n ther e i s a poin t c £ [a , 6] suc h tha t /(a ) / da(x) = f(a)(a(c) -

f{x)da{x) =

a(a)).

1.3.18. Fo r 0 < a < 6, find

inn r^^dx. 1.3.19. Fo r x > 0 , prov e tha t (a) i f F(x ) = / * + 1 sin(* 2)dt, the n |F(a;) | < 1 /x , (b) i f F ( » = / * + 1 sin(e*)cfe , the n |F(x) | < 2/(e x ). 1.3.20. Sho w tha t i f th e function s / , OL\,OL2 bounded variatio n o n [a , 6], the n b rb

a re

continuou s an d o f

pb

/ f(x)a 1 (x)da2{x)+ f(x)a

f(x)d(a1(x)a2{x)) =

JaJ

1 2{x)da

(x).

a

1.3.21. Sho w tha t i f / i s continuou s an d o f bounde d variatio n o n [a, 6], the n fo r a positiv e intege r n , rb r

b

f(x)d({f(x))n) =

nf (f(x))

n

df(x)

Ja

U

((/W)

n+ 1

n1 +

- ( / ( « ) ) n 1+ ) -

1.3.22. Suppos e tha t / i s continuou s o n [0,1 ] . Fin d th e followin g limits: (a) li m \n [ n x n f(x)dx) . n—>oo \ "

(b) li m (nfie-

u

"

J nx

f(x)dx),

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20

Problems. 1 : Th e Riemann-Stieltje s Integra l (c) Jo x

lim

J0 x

n

f{x)dx

n x2

e dx

2n

(d) li m (jnj* f(x)sm

(27rx)dxY

(e) JQ1 f(x)sin 2n(27rx)dx lim n ~*°° Jo e x2sm2n(27rx)dx ' 1.3.23. Prov e th e followin g monotone convergence theorem for the Riemann integral. I f {/ n} i s a decreasin g sequenc e o f Rieman n in tegrable function s o n [a , b] which converge s o n [a , b] to a Rieman n integrable functio n / , the n nb rb

lim / f n(x)dx = / f(x)dx. n -*°° J a J a 1.3.24. Prov e th e followin g monoton e convergenc e theore m fo r th e lower Rieman n integral . I f {f n} i s a decreasin g sequenc e o f bounde d functions o n [a , 6], and i f li m f n{x) = 0 for x E [a , 6], the n 71—•OO

rb

lim / f n(x)dx =

0.

Ja

1.3.25. Prov e th e followin g Arzela theorem. I f {/ n } i s a sequenc e o f Riemann integrabl e function s o n [a , b] whic h converge s o n [a , b] t o a Riemann integrabl e functio n / , an d i f there i s a constant M > 0 such that \f n(x)\< M fo r al l x G [a, b] an d al l n G N, the n b rb rno

no

lim / f n(x)dx = / f{x)dx. n oc -" Ja J a 1.3.26. Prov e th e followin g Fatou lemma for Riemann integrals. I f {/n} i s a sequenc e o f nonnegativ e Rieman n integrabl e function s o n [a, 6] whic h converge s o n [a , b] to a Rieman n integrabl e functio n / , then br rru

I f(x)dx < J a n-*oo

b pO

li m / J

f

n(x)dx.

a

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1.4. Prope r Integral s

21

1.4. Prope r Integral s 1.4.1. Fo r n G N , calculate (a;,) /

f4 \

x

-1 | n

(c) /

\lnx\dx , (d

(e) /

tan

(g) /

n

: : —\dx, (b ) / Jo \x — 2\ + \x — 3 | ,y

Jo

:

j0 sin

2n

n

)/

£cb, (f

)/

n

sm 0 J t

xdx, /

cos o

17

xdx,

_ 9_dx, + cos 2 x

;

dx,

Jo sin " x' +' co " "s ~x

sm x x-h cosn x-ax.

1.4.2. Fo r n E N, use the integral J Q ( l — x 2) dx 1 fn\ 1

fn\ 1

1 VOy 3

/ n\ ,

r1

v

\lj 5\2J

y

t o calculat e /

n

2 n + l V^

1.4.3. Suppos e tha t a functio n / ha s an indefinite integra l (o r antiderivative) o n an interva l I ; tha t is , there i s a differentiable functio n F suc h tha t F'{x) — f(x) fo r x G I. Sho w tha t i f a one-sided limi t of / a t xo G I exist s an d is equal t o a, the n f(xo) — a. 1.4.4. Le t / b e defined b y „ N (sin

± i f x^O,

[c i

f x = 0,

where c G [—1,1]. For which value s o f c does ther e exis t a n antideriv ative o f / ? 1.4.5. Le t xn — 1/y/n fo r n G N. Construct a function / continuou s on (0,1 ] and suc h tha t / > 0 on [x2k,X2k-i], / < 0 on [x2k+i,X2k] and F(x 2k-i) - F{x 2k) = F{x 2k+i) ~ F{x 2k) = 1 /fc , wher e F i s an antiderivative of/. Exten d the function / t o [0,1 ] by setting /(0) = 0. Prove tha t / ha s an antiderivative o n [0,1 ] , bu t | / | doe s not. 1.4.6. Suppos e / i s continuous o n [0,1 ] , Sho w tha t r

\ xf(smx)dx Jo 2

7T r

= — / f(sinx)dx. J0

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22

Problems. 1 : Th e Riemann-Stieltje s Integra l

Using thi s equality , comput e •

I

2r ?

xsm x o sin x + cos 2n x dx, n 2n

G N. 1.4.7. Assum e tha t / i s continuou s o n [—a, a], a > 0. Sho w tha t (a) a ra

/

i

f(x)dx = 2 f(x)dx,

f / i s even ,

-a JO

(b)

pa

/

f(x)dx = 0 , i f / i s odd . 1.4.8. Le t / : R— » R b e continuou s an d periodi c wit h perio d T > 0 . Prove tha t fo r ever y rea l a, —i

J

/ f(x)dx

= / f(x)dx.

Ja

JO

1.4.9. Le t / : R— > R b e continuou s an d periodi c wit h perio d T > 0 . Prove tha t fo r ever y a < 6, lim / f(nx)dx =

-—/

f(x)dx.

1.4.10. Suppos e tha t / G C ( [ - l, 1 ]) . Find th e followin g limits : (a) li m ±Cf(sinx)dx, (b) li m ^ /

n

/(|sinx|)dx,

(c) li m L xf(s'm(27rnx))dx. u

n—>oo

1.4.11. Fo r / G C([a,6]), find th e followin g limits : (a) li m f f(x) cos(nx)dx, li

m f /(# ) sin(nx)dx ,

(b) li m f f(x) si n (nx)dx. n—>oo a

1.4.12. Suppos e / G C([0,oo)) an d se t an = I f(n + x)d x fo Jo

rn

= 0,1 ,

Suppose als o tha t li m a n = a. Fin d th e limi t li m J

Q

f(nx)dx.

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23

1.4. Prope r Integral s

1.4.13. Fo r a functio n / positiv e an d continuou s o n [0,1 ] , comput e

f f(x)+f(l-x)

-dx.

1.4.14. Sho w that, i f / Jo i s continuous an d eve n on [—a , a], a > 0 , the n / " . $ ? * - ! >*• 1.4.15. Sho w tha t i f / i s nonnegative an d continuou s o n [a, b] and

f f{x)dx = 0, Ja

then / i s identicall y zer o o n [a , b]. 1.4.16. Sho w tha t i f / i s continuou s o n [a , b] and fo r eac h a,/3 , a < a< (3 0 , if / * + T f(t)dt = J QT f(t)dt fo r ever y x G R , the n / i s periodic wit h perio d T > 0 .

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24

P r o b l e m s . 1 : T h e R i e m a n n - S t ieltjes Integra l

1.4.20. Comput e

(a) ta

(„./-_**) ,

(b) li m ( n'3 f 2n xdx

\

(c) li m / I n ( x H )n dx, r2n xdx n-*coJ1 n-^oo \3TT J^ arctan(nx) 1.4.21. Fin d th e followin g limits : (a) li m / e-

Rsint

dt,

(b) li m / \/xsinxdx, (c) li m / dx. n >00 - Jo v l+ ^ 1.4.22. Fo r a functio n / continuou s o n [0,1 ] , find n

lim / f(x

)dx.

n-^ooJQ

1.4.23. Sho w that , i f / i s Riemann integrabl e o n [a , &], then ther e i s 0 G [a, b] suc h tha t

/ f(t)dt = [ f(t)dt.

Ja

JO

1.4.24. Le t / b e continuou s o n [a , 6] and le t / f(x)dx = 0.

Ja

Show tha t ther e i s 0 G (a, 6) suc h tha t

f f(x)dx = f(9).

Ja

1.4.25. Le t / G C([a,6]), a > 0 , an d le t / /(x)d z = 0 .

Ja

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25

1.4. P r o p e r Integral s Show tha t ther e i s 0 G (a, b) such tha t

f f{x)dx = 6f{6). Ja

1.4.26. Suppos e / , g G C([a, &]). Sho w tha t ther e i s 0 G (a, b) suc h that g(0) f f(x)dx =

/(0 ) / ^(x)dx .

1.4.27. Suppos e / , # E C([a, 6]). Sho w tha t ther e i s 0 G (a, 6) suc h that (/(0) / f(x)dx Ja

= f(0) [ g(x)dx. JO

1.4.28. Suppos e / an d g are positive an d continuous o n [a , b]. Show that ther e i s 0 G (a, b) such tha t =1. 1.4.29. Le t / b e positiv e an d continuou s o n [0,1 ] . Prov e tha t fo r every n G N there i s 0{n) such tha t e n Ir1 r ()r 1 — / f(x)dx = / f(x)dx + / f(x)dx. n

JO

JO

Jl-O(n)

Find th e limit lir a (n0(n)). n—>oo

1.4.30. Le t / G C^QO, 1]). Show tha t ther e i s a 0 G (0,1) such tha t

f(x)dx = f{Q)+ l-f'{0).

/* 2 Jo 1.4.31. Le t / G C ([0,1]). Sho w tha t ther e i s a 0 G (0,1) such tha t

jf 1 /(x)dx = /(0) + i// (0) + ^/ ,/(fl). 1.4.32. Suppos e / G C^IO, 1]) an d /'(()) ^ 0 . For x G (0,1], le t 0(x) be suc h tha t

r f(t)dt=f(6(x))x. Jo Find th e limi t

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26

Problems. 1 : Th e Riemann-Stieltje s Integra l

1.4.33. Suppos e / i s continuous, nonnegativ e an d strictl y increasin g on [a , b]. Fo r p > 0, le t 0(p) denot e th e uniqu e numbe r suc h tha t

(f(o(p)r = ~ j\f{x)Ydx. b a

~ J

a

Find li m 0(p). p—>oo

1.4.34. Suppos e / i s continuous o n [a , b] an d suc h tha t

f x nf(x)dx = 0 Ja

for n = 0 , 1 , . . . . Prov e tha t / i s identicall y zer o o n [a , b\. 1.4.35. Suppos e / i s continuou s o n [a , b] an d suc h tha t / x nf(x)dx = 0 Ja for n = 0 , 1 , . . . , N. Prov e tha t / ha s a t leas t N -\- 1 zeros i n [a , b]. 1.4.36. Suppos e tha t / e C([-a,a]),a >

0. Sho w tha t

(a) i f I x 2nf(x)dx = J —a

0 fo r n = 0 , l , . . . ,

then / i s odd o n [—a , a], (b) i f 1 I x 2n+ f(x)dx = 0 fo r n = 0 , 1 , . . . , J —a then / i s even o n [—a , a]. 1.4.37. Fo r / continuou s o n R , fin d

i- [ (f(x + h)-f(x))dx.

h^O h J a

1.4.38. Fo r / continuou s o n R an d a < 6, defin e

g(x)= ( f(x + t)dt. Ja

Find th e derivativ e o f g. 1.4.39. Fin d th e followin g limits :

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27

1.4. Prope r Integral s 1 (a) li m - = / I n ( 1 + 4 = ) dt, x->oo , / x Ji /I \ T

Z" 1

Vi

X

C O S

^7

(b) h m x / — f2?r-dt,

, ,T c li

m^

n si n \fidt ^ _ ,

{ I [ x Pit) \ (d) li m I —a / I n d t 1 , wher e a > 1 , an d P an d Q ar e x-^oo y ^ J 0 Q\t) J polynomials positiv e o n R + . 1.4.40. Fin d th e followin g limits : (a) li m f -— / dt)

(b)

^Gr

,

(i+sint)i +t

(c) li m (\ fV

^

dtV

(r 2 \ 1 /(*2) l (d) li m \ e dt) x ^°° \Jo ) 1.4.41. Sho w tha t i f / i s continuous o n [0,1 ] , the n lim (f \f(x)\*dx)

=

ma x \f(x)\.

1.4.42. Suppos e tha t a real-value d functio n f(x,y) i s continuou s o n a rectangl e R = [a , b] x [c , d]. Sho w tha t i{y) = / f(x,y)dx Ja is continuou s o n [c , d]. 1.4.43. Suppos e tha t a real-valued functio n f(x,y) define d o n a rectangle R = [a , b] x [c , d] is Rieman n integrabl e ove r [a , b] for eac h 2/ G [c , d], an d th e partia l derivativ e -g- is continuou s o n R . Prov e that dy

/ f(x,y)dx= /

—(x,y)dx.

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28

P r o b l e m s . 1 : T h e Riemann-Stieltje s Integra l

1.4.44. Le t / b e positiv e an d continuou s o n [0,1 ] . Fin d i/p

lim ( / (f(x)) pdx ' p-

1.4.45. Le t / b e positiv e an d continuou s o n [0,1 ] . Fin d ^ I/P lim j\f{x)fdx p—» —oo

1.4.46. Prov e tha t fo r ever y positiv e intege r N th e equatio n /t

t

e t 1+

Jo l0

' { v. +

2

2N

t + +

^. - (2Ny.]dt =

N

has a solutio n i n th e interva l (TV , 27V). 1.4.47. Le t P b e a polynomia l o f degre e n suc h tha t

f /o

Prove tha t

xkP(x)dx =

0 fo

r fe =

l,2...,n .

Jo

2

f (P(x)) 2dx =

( n + l ) 2 ^ / P(x)d ix a

1.4.48. Sho w tha t i f / i s continuous o n R = [a , b] x [c , d], the n /I

/ f{x,y)dx\dy= /

I

/ f{x,y)dy\dx.

1.4.49. Prov e tha t fo r 0 < a < b, 1

xb - x a , , 1 +6 ax = I n IQ 1 I nx +a

I

1.5. Imprope r Integral s Assume tha t / i s define d o n [a , oo) an d i s Rieman n integrabl e ove r any finite interva l [a , b]. Then w e defin e /•OO

fO

I f(x)dx = li m / f(x)dx, J ab ->°° J a provided tha t thi s limi t exist s an d i s finite. I n thi s cas e w e sa y tha t the imprope r integra l o n th e lef t converges ; otherwise , w e say tha t i t

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1.5. Imprope r Integral s

29

diverges. Th e imprope r integra l J_ f(x)dx

i s define d analogously .

The integra l J_^ f(x)dx i s defined b y + o o pa

r~\-oo

)dx

/

f(x)dx = f(x)dx+ f(x -oo J— oo Ja provided tha t bot h imprope r integral s o n th e righ t converge . Th e definition doe s no t depen d o n th e choic e o f a. For / define d o n [a , b) and Rieman n integrabl e ove r eac h close d subinterval o f [a , 6), the imprope r integra l J f(x)dx i s define d a s rb ro—r/ pb—r] ro

/ f(x)dx = li m / f(x)dx, J a ^o+ J a provided th e limi t i s finite. I f / i s define d o n (a , b] and Rieman n integrable ove r eac h close d subinterva l o f (a , 6], the imprope r integra l f f(x)dx i s defined i n a simila r way . 1.5.1. Fo r n G N and positiv e a, calculat e dx r-l*

pZTV

Jo sin c) /

4[

(b) [

:x + cos 4 x '

x n{l-x)adx, a > - l Jo Jo

, (d

e) Jop - ^ - ^ V

(f) f

x

s)

/

(T

)/

\n(sinx)dx, Jo n

(-\nx)

Jo

dx,

x n ln a xdx,

dx 7i x

dx y/x2 — 1

2

In a:

k) /

ln( l + cosa:)dx ,

(1)

rda:,

f'"K)r

+x

2 *

1.5.2. Fo r 0 < a < 1 , defin e

/a 0*0

rai

r ii

— —a — X Vx\

00+ x - » l

-

lim

/ ( * ) + / ( S ) + " + /( aJT1 )

n—»oo fl

exists a s a finite limit , the n th e imprope r integra l J 0 f(x)dx exists . 1.5.5. Sho w b y exampl e tha t i n th e precedin g proble m th e assump tion tha t on e o f th e one-side d limit s i s finite canno t b e omitted . 1.5.6. Usin g th e resul t i n 1 .5.3 , find (a) li m

n—>-oo fl

,\r

, . 7T

.

2TT

.

( n -1

u (b) li nm \ si n — s i n - - . . . sin 2n 2n 2n

\ fc=i \

)T T

fc=i /

1.5.7. Suppos e tha t th e functio n / : (0,1 ]— > R i s monoton e an d fo r some a G M the imprope r integra l j 0 x af(x)dx exists . Sho w tha t lim x a+1 f(x) = 0 . x-+0+

1.5.8. Verif y whethe r th e followin g imprope r integral s converg e o r diverge:

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1.5. Imprope r Integral s

(a)

31

L ^ ' (b

)

L IT^ '

1

(c) /

r r (-lnx)°dx , a e l , (d Jo Jo o1

l

)/

dx — - — ^ , o,ieR \ mx j

x

,

xdx + x 2 sin 2 x

1.5.9. Suppos e tha t / an d g ar e positiv e o n [a , oo) an d J a°° g{x)dx diverges. Sho w tha t a t leas t on e o f th e integral s / f(x)g(x)dx, Ja Ja

/

dx

-Tr^ f{

X

)

diverges. 1.5.10. Prov e th e followin g Cauchy theorem. I n orde r tha t th e im proper integra l J a°° f(x)dx converge , a necessary an d sufficien t condi tion i s that, give n e > 0, ther e i s a^ > a suc h tha t fo r a2 > a\ > ao, a

r 22 I />a

/(z)da; < £. J a\

1.5.11. Sho w tha t th e imprope r integra l J f(x)dx converge s i f an d only if for every increasing sequence {a n }, an > a , divergin g to infinit y the serie s ^ /*a

(1) }

n

\ J/ / f(x)dx, n = 1

wher

ea

0

= a,

^an_i

converges. Moreover , i n th e cas e o f convergence ,

/ f(x)dx

=

j ; / /(*)£*!;

.

Show als o tha t i f / i s nonnegative, a sufficien t conditio n fo r th e con vergence o f th e imprope r integra l i s tha t ther e i s a n increasin g se quence {a n }, a n > a, divergin g t o infinit y fo r whic h th e serie s (1 ) converges. 1.5.12. Fo r positiv e a, stud y th e convergenc e o f th e integra l

I

o1

dx + x a sin 2 x

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32

Problems. 1 : Th e Riemann-Stieltje s Integra l

1.5.13. Suppos e / i s positive o n [0 , oo) an d f Q f(x)dx exists . Mus t f(x) ten d t o zer o a s x — » oo ? 1.5.14. Suppos e / i s positive, differentiable o n [a , oo), and \f'(x)\ < 2 for x > a. Doe s th e convergenc e o f J°° f(x)dx impl y tha t f(x) tend s to zer o a s x — > oo ? 1.5.15. Prov e tha t i f / i s uniforml y continuou s o n [a , oo) an d th e improper integra l f °° f(x)dx converges , the n li m f(x) = 0 . 1.5.16. Assum e tha t / : [0 , oo)— * [0,oo) i s monoton e decreasing . Prove tha t i f

then li m xf(x) =

f(x)dx
oo

hold; tha t is , th e conditio n li m xf(x) —

0 doe s no t impl y th e con -

x—>oo

vergence o f J 0 f(x)dx. 1.5.17. Assum e tha t / : [1 , oo)— > (e , oo) i s monotone increasin g an d f°° dx

h fix) f °° dx (a) Prov e tha t als o / —•— —— = oo. :ln/(x) (b) Giv e an example of a function / satisfyin g th e abov e assump dx r x l n / ( x ) l x ) )converges . tion fo r whic h / _ ^ £f ^ ^ n n( l_n£f/ („w

1.5.18. Le t / b e a continuou s functio n o n [0 , oo) suc h tha t lim (fix)-]- f f(t)dt] ^°° \ Jo / exists a s a finite limit . Prov e tha t li m f(x) = 0 . x

x—>-oo

1.5.19. Le t / b e a nonnegativ e an d continuou s functio n o n [0 , oo) and Jo Jo

Prove tha t

f(x)dx
0 such tha t f(t)dt
0 ) wit h / 0°° g(x)dx < oo. The n /»oo p\

/ f(x)g(x)dx Jo Jo

R b e a nonnegativ e decreasin g functio n an d let g : [a , b] —> R b e a nonnegativ e an d Rieman n integrabl e functio n such tha t

/

J aJ

g

2{t)dt

a

and rb nb

/ gi (t)dt= / J aJ

g

2(t)dt,

a

Show tha t i f / i s increasing o n [a , 6], the n nb

/»6

/ f(t)

9l(t)dt
f f(t)g 2(t)dt. J aJ

a

1.6.43. Us e the Steffense n inequalit y t o prov e tha t i f / i s contin uously differentiat e o n [a , b] and m < f'(x) < M (m < M) fo r x G [a, b], then +

(M - m)A 2 /(& ) - / ( a ) ( (6-a) 2 " 6a~ (b

M - m)(f r - a - A) - a) 2

2

where A

/(&)-/(a)-m(6-a) M -m

1.6.44. Prov e tha t i f / i s continuousl y differen t iable o n [a , b] and m < f'(x) < M (m < M) fo r x e [a , 6], the n / f{x)dx (b-a)\
0.

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1.7. J o r d a n M e a s u r e

55

1.7.19. Sho w t h a t a bounde d se t A i s Jorda n measurabl e i f an d onl y if ther e exis t tw o sequence s { B n } an d { C n } o f J o r d a n measurabl e sets suc h t h a t B n C A C C n an d li m | B n | = li m | C n | = | A | . n—>oo n—>o

o

1.7.20. Sho w t h a t th e se t A=|(x,|/)Gl

2

: 0 < x < l ,0

< y
0 , consist s o f thre e con gruent leaves , tangen t t o eac h othe r a t th e origin . Fin d th e are a o f one o f th e leaves . 1.7.25. Fin d th e are a o f th e limago n r = a + bcosO, wher e positiv e numbers a an d b ar e given , distinguishin g th e case s i n whic h a > b, a = 6 , an d a < b. 1.7.26. Fin d th e are a o f th e loo p o f th e curv e x 5 + y 5 = 5ax where a > 0 i s given .

2 2

y,

1.7.27. Fin d th e are a o f th e regio n t h a t lie s withi n t h e limago n r = 1 + 2 cos 6 an d outsid e th e circl e r = 2 .

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56

Problems. 1 : Th e Riemann-Stieltje s Integra l

1.7.28. Suppos e / i s nonnegativ e an d continuou s o n [a , b]. A plan e region A / = {(x,y) £ M 2 : a < b, 0 < y < f(x)} i s revolve d abou t the x-axis , generatin g a solid o f revolution V wit h volum e |V| . Prov e that |V| = 7 T / f\x)dx. Ja 1.7.29. Suppos e / i s nonnegative an d continuou s o n [a , b] and 0 < a. Prove tha t th e volum e o f th e soli d V generate d b y th e plan e regio n Af = {(x,y) G M 2 : a < 6, 0 ( 2k + i) 71 "] a b o u t t h

e

x-axis. 1.7.32. Sho w tha t th e lengt h L o f the ellips e

©Mir-

satisfies 7r(a + b) < L < 7r^2{a 2 + b 2).

1.7.33. Sho w tha t th e lengt h o f th e ellips e

is given b y

where e = ~

b

i s th e eccentricit y o f th e ellipse .

1.7.34. Deriv e th e followin g formul a fo r th e lengt h o f a curv e i n th e polar coordinate s (r , 6). I f / i s continuousl y differen t iable o n [a,/?] , then th e lengt h L o f th e curv e r = /(0) , a < 9 < (3, i s give n b y

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57

1.7. J o r d a n M e a s u r e 1.7.35. Fin d th e lengt h o f th e curv e wit h pola r equatio n Q

(a) r = a s i n 3 - , 0 o

< 6 < 3TT.

( b ) r =~i l —E> ~ f < ^ < f K; 1 + co s 0 2 - 2 1.7.36. Fin d th e lengt h o f the curv e wit h pola r equatio n

0 = \(r + iy l 0 there i s a n open se t G suc h that A C G an d ra(G) < ra*(A) +£ . Sho w als o tha t there i s a Q$ se t A 2 suc h tha t A C A 2 an d ra(A 2) = m*(A) . 2.1.12. Prov e that fo r A C R the following statements are equivalent : (i) A i s measurable . (ii) Give n e > 0 , ther e i s a n ope n se t G D A suc h tha t m*(G\A) 0, ther e i s a close d se t F C A suc h tha t m*(A\F) 0 there i s a finite unio n W o f open interval s suc h tha t ?7i* (W A A ) < £ , wher e W A A i s th e symmetri c differenc e fo r W and A , tha t is , W A A = ( W \ A ) U (A \ W) . 2.1.14. Fo r A C R , defin e th e Lebesgue inner measure m*(A ) o f A by settin g ra*(A) = sup{ra(B ) : B e S0t , B c A } , where 9J t denotes th e a-algebr a o f al l measurabl e subset s o f R. Prove : (a) I f A i s measurable , the n m * (A) = ra*(A). (b) I f A i s a subse t o f a bounde d close d interva l I , the n m*(A) = |I | - r a * ( I \ A) . (c) I f ra* (A) = m*(A ) < oo , the n A i s measurable . (d) Fo r an y set s A an d C , m*(A U C) + ??7 * (A H C) > ra*(A) + 7n*(C) . (e) I f A n , n = 1 ,2,... , ar e pairwis e disjoint , the n 777* ( | J A \n = l I

n

J > ^m^An). n

=l

(f) I f M i s o f measur e zero , the n m* (A U M) — m*(A).

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62

Problems. 2 : Th e Lebesgu e Integra l

2.1.15. Prov e tha t A C I, wher e I i s a bounde d an d close d interval , is measurabl e i f an d onl y i f |I| = m * ( A ) + m * ( I \ A ) . 2.1.16. Le t A an d B b e given sets of finite outer measure . Sho w tha t m * ( A u B ) = m*(A ) 4-m*(B) i f and onl y i f there ar e measurable set s Ai an d B i suc h A C A i , B C B i an d ra(Ai n Bi ) = 0 . 2.1.17. Le t A an d B b e given sets of finite outer measure . Sho w tha t if ra*(AUB) = r a * ( A ) + m*(B) , t h e n r a * ( A u B ) = ra*(A) + m*(B) . 2.1.18. Prov e tha t i f {A n } i s a n increasin g sequenc e o f measurabl e sets, the n m I Iv J/ A n -- l // \n=

J = li m m ( A n ) . n,

—»oo

2.1.19. Prov e tha t i f {A n } i s a decreasin g sequenc e o f measurabl e sets an d ra(Afc) i s finite fo r a t leas t on e fc, then m I P i A n J = li m m ( A n ) . \' ' / \n=l J

n—>o

o

Show als o tha t th e assumptio n tha t ra(Afc) < o o fo r som e k canno t be omitted . 2.1.20. Fo r a sequence {A n } o f sets in R, we define th e limi t superio r and th e limi t inferio r o f {A n } b y settin g oo

lim A

n

oo

oo

= p | I ) A n an d li

mA

n ~^°° , -, 7 n-^oc 1 k=ln=fc K= n=k

n

oo

= ( J p | A n.

,

1

,

(a) Sho w tha t i f A n , n G N, ar e measurable , the n m I li m A \n—+oo J

n

1 < li m m(A n ). n—

>-oo

(b) Sho w that if , moreover , m(A n U one n , the n

An + i U . . .) < o o for a t leas t

m l li m A n 1 > li m m ( A n ) . \n—>oo /

n—>-o

o

2.1.^1. W e say that a sequence {A n } of sets in R converges if li m A n—>oo = li m A n , an d w e denot e th e commo n valu e b y li m A *-n* ^

n

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63

2.1. Lebesgu e Measur e o n th e Rea l Lin e (a) Sho w tha t a monotoni c sequenc e o f set s converges .

(b) Sho w that , i f a sequenc e {A n } o f measurabl e sets , A n C B , where ra*(B) < oo , converges , the n m ( li m A n ) = li m ra(A \n—>oo /

n—->o

n).

o

2.1.22. Sho w tha t th e Lebesgu e measur e o f th e se t A define d i n 1.7.12 i s equal t o 1 — a. 2.1.23. Le t A b e th e se t o f points i n [0,1 ] suc h tha t x i s in A i f an d only if the decimal expansio n o f x doe s not requir e th e us e of the digi t 7. Sho w tha t A ha s Lebesgu e measur e zero . 2.1.24. Le t B c M b e th e se t o f al l number s whos e decima l expan sions d o no t requir e th e us e o f th e digi t 7 afte r th e decima l point . Show tha t B ha s Lebesgu e measur e zero . 2.1.25. Le t A b e th e se t o f point s i n [0,1 ] whic h admi t o f binar y expansions with zeroes in all even positions. Sho w that A i s a nowhere dense se t o f Lebesgu e measur e zero . 2.1.26. Fin d th e Lebesgu e measur e o f the se t o f points i n [0,1 ] whic h admit decima l expansion s containin g al l th e digit s 1 , 2 , . . ., 9 . 2.1.27. Wha t i s th e Lebesgu e measur e o f th e se t o f point s i n [0,1 ] which admi t decima l expansion s 0.di^2^ 3 . • • suc h tha t n o sequenc e d^k+i^3/c+2^3/c+3 consist s o f thre e consecutiv e 2's ? 2.1.28. Le t A b e th e unio n o f interval s centere d a t point s o f th e Cantor se t an d eac h o f lengt h 0.1 . Fin d th e Lebesgu e measur e o f A . 2.1.29. Sho w tha t i f A i s a bounde d measurabl e se t o f measur e ra(A) = p > 0 , the n fo r eac h q G (0,p ) ther e i s a measurabl e se t B C A o f measur e q. 2.1.30. Sho w that i f 0 < ra(A) < oo , then for each positive q < ra(A) there i s a measurabl e se t B C A o f measur e q. 2.1.31. Sho w that i f 0 < ra(A) < oo , then for each positive q < ra(A) there i s a perfec t se t B C A o f measur e q. 2.1.32. Sho w tha t an y se t A o f positiv e Lebesgu e measur e ha s th e cardinality o f th e continuum .

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64

Problems. 2 : Th e Lebesgu e Integra l

2.1.33. Sho w tha t an y nonempt y an d close d se t A C R o f Lebesgu e measure zer o i s nowher e dense . 2.1.34. Suppos e tha t A C i i s a nowher e dens e se t o f Lebesgu e measure zero . Mus t it s closur e b e o f Lebesgu e measur e zero? 2.1.35. Sho w tha t i f A C [a , b] an d ra(A) > 0 , the n ther e ar e x an d y in A suc h tha t \x — y\ i s a n irrationa l number . 2.1.36. Doe s ther e exis t a countable collectio n o f nowhere dens e an d perfect subset s o f [0,1 ] whos e unio n i s of Lebesgu e measur e 1 ? 2.1.37. Doe s ther e exis t a nowher e dens e an d perfec t subse t o f [0,1 ] of Lebesgu e measur e 1 ? 2.1.38. Giv e a n exampl e o f a measurable se t A C R wit h th e follow ing property : Fo r eac h interva l (a,/3) , ra(An(a,/?)) >

0 an d ra((R \

A ) n (a,/?) ) > 0 .

2.1.39. Assum e tha t a measurabl e se t A C R ha s th e propert y tha t for eac h 8 > 0, m ( A f l ( 4, 5)) > 0 and 0 £ A . Prov e that ther e exist s a perfec t se t B C A suc h tha t ra(B H (—6, 5)) > 0 for ever y S > 0 . 2.1.40. A measurable se t A C R i s said t o hav e density d at x if th e limit m(An\x-h,x + h\) hm — —— — /i—o+ 2h

exists an d i s equal t o d. I f d — 1, then x i s called a point of density of A, an d i f d — 0 , the n x i s called a point of dispersion of A. Fin d th e points o f density an d point s o f dispersion o f A = (—1 , 0)U(0,1)U{2}. 2.1.41. Give n a £ (0,1 ) , construc t a se t A whos e densit y a t XQ £ R is equa l t o a. 2.1.42. Le t A b e a measurabl e se t suc h tha t 0 £ A i s a poin t o f density o f A . Prov e tha t ther e i s a perfec t se t B C A suc h tha t 0 is a poin t o f densit y o f B . 2.1.43. I f x an d y ar e i n [0,1 ) , we define th e su m x + y(mod 1 ) to b e x - f y, i f x + y < 1 , an d t o b e x + y — 1 , i f x + y > 1 . Fo r A C [0,1 ) and a £ [0,1 ) , w e defin e th e translat e modul o 1 of A t o b e th e se t A - f a(mo d 1 ) = {x - f a (mod 1 ) : x £ A} . Show tha t ?n* (A) = m*( A + a(mo d 1 )) .

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2.1. Lebesgu e Measur e o n th e Rea l Lin e

65

2.1.44. Sho w tha t i f A C [0,1 ) an d a G [0,1 ) , the n th e se t A + a (mod 1 ) i s measurabl e i f an d onl y i f A i s measurabl e an d ra(A + a(mo d 1 ) ) = m(A) . 2.1.45. W e sa y tha t x,y G [0,1 ) ar e equivalent , an d writ e x ~ y , i f and onl y i f x — y i s a rational . Thi s equivalenc e relatio n partition s [0,1) int o a n uncountabl e famil y o f disjoin t equivalenc e classes . B y the axiom of choice there is a set V whic h contains exactly one element from eac h equivalence class . W e call any such a set a Vitali set. Prov e that a Vital i se t i s nonmeasurable . 2.1.46. Sho w that i f A i s a measurable subse t o f a Vitali se t V , the n ra(A) = 0 . 2.1.47. Show , b y example , tha t th e convers e o f th e resul t state d in 2.1 .1 7 i s no t true ; tha t is , ther e exis t set s A an d B suc h tha t ra*(A U B) = ra*(A) + ra*(B) bu t ra*(A U B) < ra*(A) + ra*(B). 2.1.48. Sho w tha t an y se t o f positiv e oute r measur e contain s a non measurable subset . 2.1.49. Giv e a n exampl e o f a sequence {A n } o f pairwise disjoin t set s such tha t

(

oo \

o

c

(J A n c} is measurabl e fo r ever y c G C. 2.2.5. Sho w tha t a real-value d functio n / define d o n a measurabl e set A i s measurabl e i f an d onl y i f / - 1 ( G ) i s measurabl e fo r ever y open G C R . 2.2.6. Sho w tha t i f a real-value d functio n / define d o n R i s measur able, the n / _ 1 ( B ) i s measurabl e fo r ever y Bore l se t B C R . 2.2.7. Prov e tha t continuou s real-value d function s define d o n mea surable set s ar e measurable . 2.2.8. Suppos e extended-value d function s / an d g ar e define d o n a measurable se t A . Prov e tha t i f / i s a measurable functio n an d f — g a.e., the n g is measurable . 2.2.9. Prov e tha t ever y Rieman n integrabl e functio n define d o n [a , b] is measurabl e o n [a , b]. 2.2.10. Sho w tha t eac h functio n o f bounde d variatio n o n [a , b] is measurable. 2.2.11. Defin e th e Cantor function ip : [0,1 ]— > [0,1] a s follows : I f oo

x i s a n elemen t o f th e Canto r se t C an d x — Yl &t with a n = 0 o r 71=1

an = 2 , the n w e pu t

(

oo \

o

o 1

Z^ 3 n J Z-J

n=l /

n=

2

l

2

n

that is , i f a n i s th e nt h ternar y digi t fo r x , the n th e nt h binar y digi t for 0, there i s a measurable se t B C A suc h tha t ra(A\B) < e and / restricte d t o B i s bounded . 2.2.22. Prov e th e followin g Egorov theorem. Le t A C R b e a mea surable se t o f finit e measure . I f {f n} i s a sequenc e o f measurabl e functions whic h converge s t o a real-value d functio n / almos t every where o n A , then , give n e > 0, ther e exist s a measurabl e subse t B o f A suc h that ra(A\B) < e and th e sequenc e {f n} converge s uniforml y to / o n B .

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70

Problems. 2 : Th e Lebesgu e Integra l

2.2.23. Sho w by example that th e assumption m(A) < o o is essential in th e Egoro v theorem . 2.2.24. Suppos e tha t A i s measurabl e an d {f n} i s a sequenc e o f measurable function s whic h converge s t o / almos t everywher e o n A . Prove that ther e is a set B C A suc h that B = I J ^ i B* , ra(A\B) = 0 and th e sequenc e {f n} converge s uniforml y t o / o n ever y B^ . 2.2.25. Le t {V n } b e th e sequenc e o f set s define d i n th e solutio n t o 2.1.45 an d le t {f n} b e th e sequenc e o f function s o n [0,1 ) define d b y fn = X\J°l Vi- Sho w tha t f n— » 0 o n [0,1 ) , bu t th e assertio n o f th e Egorov theore m doe s not hold , that is , there i s e > 0 such that o n any measurable subse t B o f [0,1 ) wit h m([0,1 ) \ B ) < e th e convergenc e is no t uniform . 2.2.26. Construc t a sequenc e {f n} o f measurabl e function s o n [0,1 ] such tha t th e sequenc e converge s everywher e o n [0,1 ] bu t fo r ever y set B C [0,1 ] o f measur e 1 , th e sequenc e fail s t o converg e uniforml y onB. 2.2.27. Prov e th e followin g Lusin theorem: I n orde r tha t a real valued functio n / define d o n a measurabl e se t A b e measurable , a necessary an d sufficien t conditio n i s tha t fo r ever y e > 0 ther e i s a closed se t F C A suc h tha t ra(A \ F ) < e an d / restricte d t o F i s continuous. 2.2.28. Usin g the result i n 2.1.38, construct a function / , measurabl e on M , such tha t fo r an y se t E o f measur e zero , / i s not continuou s a t any poin t i n M \ E . 2.2.29. Le t / : [0, a]—> R b e a measurable function . Sho w that ther e exists a monoton e decreasin g functio n g o n [0 , a] such tha t fo r an y real y, m({x E [0,a ] : f(x) > y}) = m{{x e [0 , a] : g{x) > y}). 2.2.30. Le t {f n} b e a sequenc e o f real-value d function s measurabl e on A . W e sa y tha t {f n} converges in measure t o a measurabl e func tion / i f fo r ever y e > 0 , li m m({x e A : \f n(x) — f(x)\ > e}) — 0 . n—*oo

Show tha t i f a sequenc e {f n} converge s i n measur e t o / an d {f converges i n measur e t o g, the n / = g a.e . o n A .

n}

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2.3. Lebesgu e Integratio n

71

2 . 2 . 3 1 . Prov e th e followin g theorem of Lebesgue. I f 771 (A ) < 0 0 an d {fn} converge s t o / a.e . o n A , the n {f n} converge s i n measur e t o / . 2 . 2 . 3 2 . Sho w b y exampl e t h a t th e assumptio n ra(A) < in th e Lebesgu e theore m state d above .

0 0 i s essentia l

2 . 2 . 3 3 . Giv e a n exampl e o f a sequenc e o f measurabl e function s o n th e interval [0,1 ] t h a t converge s i n measur e o n [0,1 ] bu t i s no t convergen t at an y poin t o f t h a t interval . 2 . 2 . 3 4 . Le t {f n} b e th e marchin g sequenc e define d i n th e solutio n to th e previou s problem . Fin d a subsequenc e o f i t t h a t converge s t o the zer o functio n a.e . o n [0,1 ] . 2 . 2 . 3 5 . Prov e th e followin g Riesz theorem. Ever y sequenc e {/ n } con vergent i n measur e t o / o n A contain s a subsequenc e convergin g t o / a.e . o n A . 2 . 2 . 3 6 . Le t {f n} t> e a sequenc e o f monotonicall y increasin g function s on (a , b). Sho w t h a t i f th e sequenc e converge s i n measur e t o / , the n lim f n(x) — f\x) a t eac h poin t x o f continuit y o f / . n^oo

2 . 2 . 3 7 . Prov e th e followin g Frechet theorem. I f / i s a real-value d measurable functio n o n A , the n ther e i s a n T a se t H suc h t h a t ra(A \ H ) = 0 an d / restricte d t o H i s i n th e firs t Bair e clas s (tha t is, / i s a pointwis e limi t o f a sequenc e o f continuou s function s o n H ) . 2 . 2 . 3 8 . Prov e th e followin g Vitali theorem. I f / i s a real-value d mea surable functio n o n A , the n ther e i s a functio n g i n th e secon d Bair e class (tha t is , g i s a pointwis e limi t o f a sequenc e o f function s i n th e first Bair e clas s o n A ) suc h / = g a.e .

2.3. Lebesgu e Integratio n n

T h e Lebesgu e integra l o f a simpl e functio n r}) = 0 fo r som e rea l numbe r r . I n this cas e w e define th e essential supremum o f / b y H/lloo = inf{ r : m({x € A : \f(x)\ > r}) = 0} . Then th e se t E = {x e A : |/(a;) | > ||/||oo } i s o f measur e zer o an d |/0r)| < H/llo o outsid e E . Thu s | / ( x ) | < | | / | U a.e . We wil l ofte n us e th e followin g theorems : Theorem 1 (Lebesgue' s Monoton e Convergenc e Theorem) . Suppose {f n} is an increasing sequence of nonnegative measurable functions on A . If f(x) = li m f n{x), x E A, then lim / f ndm = / fdm. ^°° J A J A Theorem 2 (Fatou' s Theorem) . Suppose {f n} is nonnegative and measurable functions on A. Then n

/ Ui n fndm < li m / f J A n—>o o n—*oo

a sequence of

ndm.

JA

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73

2.3. Lebesgu e Integratio n

Theorem 3 (Lebesgue' s Dominate d Convergenc e Theorem) . Suppose {f n} is a sequence of measurable functions on A and f(x) = lim f n(x), x G A. If there exists a function g integrable on A and n—>oo

g{x), n = 1 , 2 , . . ., x G A, then

such that \f n(x)\
0 ther e i s S > 0 suc h tha t fo r ever y measurable subse t B o f A , J B \f n\dm < e fo r n = 1 ,2,.. . when ever m (B) < # . Show tha t i f {/ n } i s a convergen t sequenc e o f equi integrable function s o n a set A o f finite measure , the n lim / fndm — / li m f ndm. ~ °° J A J An ^°° 2.3.21. Prov e th e following versio n o f Lebesgue's dominate d conver gence theorem . Suppos e {f n} i s a sequenc e o f measurable function s converging i n measur e o n A t o / . I f ther e exist s a functio n g in tegrable o n A an d suc h tha t |/ n (a:)| < g(x), n = 1 ,2,... , x G A, then n >

lim / fndm — \ fdm. ™-*°° J A J

A

2.3.22. Sho w tha t th e theore m state d i n 2.3.2 0 remain s tru e whe n convergence i s replaced b y convergence i n measure . 2.3.23. Suppos e th e sequence {f n} converge s i n measur e t o / o n a set A o f finite measure , an d \f n(x)\ < C fo r x G A, n = 1 ,2,... . Show tha t i f g is continuous o n [—C , C], the n I™ / g{f n)dm= / g(f)dm. -*°° J A J A 2.3.24. Suppos e tha t {f n} i s a sequence of functions define d o n a set A o f finite measur e tha t converge s i n measure o n A t o /. Sho w tha t n

lim / s'm(f n)dm = / sin(/)d r ^°° J A J A

n

2.3.25. Suppos e / G Lp[a, b], 1 < p < oo . Show that , give n e > 0, there is (i) a simple functio n{x)\ : x e [o,6] } > 1 / 2 for al l step function s ip.

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77

2.3. Lebesgu e Integratio n

2 . 3 . 2 7 . Suppos e / G L p[a,b],1 < p < oo . Sho w t h a t , give n £ > 0 , there i s a continuou s functio n g suc h t h a t L u\f — g\ pdm < e. 2 . 3 . 2 8 . Show , b y example , t h a t th e resul t i n th e previou s proble m i s false i f p = oo . 2 . 3 . 2 9 . Suppos e t h a t g satisfie s a Lipschit z conditio n o n R . Prov e t h a t i f {/ n } i s a sequenc e o f measurabl e function s o n [a , b] t h at con verges i n measur e t o / an d ther e i s a Lebesgu e integrabl e functio n G such t h a t \f n(x)\ < G(x), the n

lim / g{f

n)dm

= / g{f)dm.

J[a,b] ^^JlaM[a,6] J\aM

2 . 3 . 3 0 . Suppos e t h a t 1 < p < oo , an d t h a t / i s measurabl e o n A and suc h t h a t \f\ p i s integrabl e o n A . Prov e t h a t , give n e > 0 , ther e is a continuou s functio n g vanishin g outsid e a finite interva l an d suc h that / \f-g\Pdm > g a.e. Sho w t h a t f ngn— > / ^ i n L p [a,6]. 2 . 3 . 3 3 . Sho w t h a t i f / i s a n essentiall y bounde d functio n o n [a . 6], then

lim If \J7dm

) =!i/lk

-

(Compare wit h 1 .4.41 . )

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78

Problems. 2 : Th e Lebesgu e Integra l

2.3.34. Prov e th e Jensen inequality for Lebesgue integrals (se e als o 1.6.29). Suppos e tha t / i s Lebesgue integrable o n [a , b]. If if is convex on R , the n (f - / fdm \b-aJ[aM J

/

< b

a5}, then 2

2

m(As)>m(A)(l-5) j. 2.4. Absolut e Continuity , Differentiatio n an d Integration A real-valued functio n / define d o n [a , b] i s said t o b e absolutely continuous o n [a , b] if , give n e > 0, ther e i s 5 > 0 such tha t n

J2\f(xk)-f(x'k)\oo x—

»oo

2.4.20. Le t / G Lp[a, 6] , 1 < p < oo , an d pu t f(x) = 0 for x £ [a , b}. For h > 0 , w e defin e fh b y settin g px+h

A M - S £»'«>*• Show tha t fh i s continuous an d \\fh\\p < II/li p (compar e wit h 1 .6.34) . 2.4.21. Prov e tha t i n th e notatio n an d unde r th e assumption s o f 2.4.20 limL||/ft-/|| p = 0 . h—>0

2.4.22. Suppos e tha t / G L l[a,b] an d tha t x G (a , b) i s suc h tha t f{x) ^ ±oo . The n x i s calle d a Lebesgue point for fit f>x+h

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2.4. A b s o l u t e C o n t i n u i t y , D i f f e r e n t i a t i o n . . .

83

Show t h a t i f x i s a Lebesgu e poin t fo r / , the n th e functio n F(x) = J f(t)dt i s differentiabl e a t x an d F'(x) — f(x). 2 . 4 . 2 3 . Sho w t h a t eac h poin t o f continuit y o f / £ L l[a, b] is a Lebes gue poin t fo r / . 2 . 4 . 2 4 . Prov e t h a t almos t ever y poin t o f [a , b] is a Lebesgu e poin t fo r

2 . 4 . 2 5 . Sho w t h a t almos t al l point s o f a measurabl e se t A ar e point s of densit y o f A . (Se e 2.1 .4 0 fo r th e definitio n o f a poin t o f density. ) 2 . 4 . 2 6 . A se t A C R i s sai d t o hav e outer density d at x i f t h e limi t ra*(An \x

lim — h-+o+ 2h

- h,x + h\)

exists an d i s equa l t o d. I f d = 1 , the n x i s calle d a point of outer density of A, an d i f d = 0 , the n x i s calle d a point of outer dispersion of A. Prov e th e followin g generalizatio n o f th e resul t i n th e previou s problem. I f A i s an y se t (measurabl e o r not) , the n almos t al l point s i n A ar e point s o f it s oute r density . A necessar y an d sufficien t conditio n t h a t A b e measurabl e i s t h a t almos t al l point s i n A c ar e point s o f outer dispersio n o f A . 2 . 4 . 2 7 . Assum e t h a t a real-value d functio n / (measurabl e o r not ) i s defined o n [a , b]. W e sa y t h a t XQ £ [a , b] i s a point of approximate continuity of f i f fo r eac h e > 0 , l i m m*([x h-^o 2h

0

- fe,s

0

+ h] H {x G [a , 6] : \f(x) -

f(x 0)\ >

g»=

Q

Prove t h a t a real-value d functio n / i s measurabl e o n [a , b] if an d onl y if almos t al l point s o f [a , b] are point s o f approximat e continuit y o f / . 2 . 4 . 2 8 . Sho w t h a t a Lebesgu e integrabl e functio n o n [a , b] is approx imately continuou s a t eac h o f it s Lebesgu e points . Sho w b y exampl e t h a t th e convers e i s no t true . 2 . 4 . 2 9 . Sho w t h a t i f / i s measurabl e an d bounde d o n [a , 6], the n x G (a , b) i s a Lebesgu e poin t fo r / i f an d onl y i f x i s a poin t o f approximate continuit y o f / .

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84

Problems. 2 : Th e Lebesgu e Integra l

2.4.30. A n alternate definitio n o f approximate continuit y i s that / i s approximately continuou s a t xo provided ther e i s a measurable se t A such tha t xo is a point o f density fo r A an d such tha t th e restrictio n of / t o A i s continuous a t x$. Sho w tha t thi s definitio n i s equivalent to th e one given i n 2.4.27. 2.4.31. Giv e a n example o f a bounded functio n / : [0,1]—> R whic h is not Rieman n integrabl e bu t i s a derivativ e o f some functio n F on [0,1]2.4.32. Suppos e / i s integrable o n [a , b] an d for t £ R defin e G(t) = m({x e [a,b] : f(x) < t}). Prov e tha t pb rOG

/ f(x)dx = / td(G(t)), J — oo

Ja

where oo /*

/

0 /»o

o

td{G{t)) = I td(G(t))

+ / td(G(t))

— oo JO

-oo J

pO nB

= li m / td{G(t))+ li m / td(G(t)). 2.5. Fourie r Serie s For / G L1[—7r,7r], the Fourier coefficients o f / a r e give n by an — — f(x)

cosnxdx, b

^ 7-7 T

n

= — / / ( # ) sinnxdir. ^ 7-7 T

The serie s 1° ° -ao + / J ( a n cos nx-f - 6n sin nx) 2

n=

l

is the Fourier series of f, an d we write ^

oo

/(#) ~ -a o + Y ^ ( a n c o s n x + 6 n sinnx). 2' n=l

We denot e b y s n{x) th e nt h partia l su m of th e Fourie r serie s o f / ; n

that is , sn{x) — \a§ + Yl (dk cos kx + bk sin fcr). fc=i

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2.5. Fourie r Serie s

85

2.5.1. Sho w tha t i f p n = y a ^ + b*^, the n oo

oo

2_"(o>n

c o sn x

+ b n sinnx) = \ J p n sin(n:r + a n ) ,

n=l n=

l

with som e a n. 2.5.2. Sho w tha t i f a n an d 6 n ar e th e Fourie r coefficient s o f / £ L1[—7r, 7r], the n lim a n = li m b n = 0 . n—»oo n—>o

o

2.5.3. Suppos e tha t / i s a 27r-periodic function tha t satisfie s th e Lip schitz conditio n o f orde r a ( 0 < a < 1 ) ; tha t is , f(x + h) — f(x) = 0(\h\a) a s / i— > 0 uniforml y wit h respec t t o x. Sho w tha t i f a n an d bn ar e th e Fourie r coefficient s o f / , the n an = 0(n- a) an

d6

= 0(n _ Q ! ).

n

2.5.4. Sho w tha t i f / i s of bounde d variatio n o n [—7r,7r] , the n a n — 0 ( n _ 1 ) an

db

n

= 0{n~

l

).

2.5.5. Sho w tha t i f / i s a 27r-periodi c functio n tha t i s absolutel y continuous o n [—7r,7r] , the n an = o(n _ 1 ) an d b

n

— o{n~ l).

2.5.6. Sho w tha t i f / i s a 27r-periodi c functio n an d / G Cfc (R), the n an = o(n~ k) an

db

n

— o(n~ k).

2.5.7. Sho w that fo r / G Ll[—TT, 7r], the nth partia l sum of the Fourie r n

series o f / , tha t is , s n(x) = \a$ -f - ^ (a ^ coskx + 6 ^ sin/ex), i s give n fc=i

by 7r t/_7r 2 s m ^ ( t - x

)

2.5.8. Asum e tha t / i s a periodic functio n o n R wit h perio d 27T , and that / i s integrable o n [—7r , TT]. Sho w that i f s n denote s the nth partia l sum o f th e Fourie r serie s o f / , the n

Snix) = - [^ (/(* + t) + f(x - t)) TT J0 2

Sin n+

(

p^.

sin %t

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86

Problems. 2 : Th e Lebesgu e Integra l

2.5.9. Prov e the Dini-Lipschitz test for convergence of Fourier series. Suppose / i s a periodic function o n R with period 2TT that i s integrable on [—7r,7r] . I f / satisfie s th e conditio n \f(xo + t) — /(#o) | < L\t\ a fo r \t\ < 8 with som e positive L , 8 and 0 < a < 1 , then th e Fourie r serie s of / a t XQ converges t o f(xo). 2.5.10. Prov e th e Dirichlet-Jordan test for convergence of Fourier series. Assum e tha t / i s a 27r-periodi c functio n integrabl e o n [—7r,7r] and tha t / i s of bounded variatio n o n [xo — 8, XQ - f 8] . Show tha t th e Fourier serie s o f / a t XQ converges t o |(/(#o~ ) + /(#o~)) 2.5.11. Sho w b y exampl e tha t th e Dirichlet-Jorda n tes t doe s no t include th e Dini-Lipschit z tes t an d tha t th e Dini-Lipschit z tes t doe s not includ e th e Dirichlet-Jorda n test . 2.5.12. Sho w tha t oo

7r — x v-

^ si n nx 71=1

and deduc e tha t 7r ^- ^ sin(2 n — l)x 4_ ^ 2 n -1 '

0 < X < 7T ,

71 = 1

IT

1

4

= 1

1

- 3

2 ^5

1 +

5 - 7

+

7 1 11

- ' 3

2.5.13. Fo r x G (0, 27r), find th e sum s o f th e followin g series : OO

E

OO

cosnx Y

n=l n =

2

n ^

^ sinn x n

3

l

2.5.14. Sho w tha t i n 2.5. 4 bi g O' s canno t b e replace d b y littl e o's . 2.5.15. Le t / b e a 27r-periodic function suc h that f(x) = E ^- fo r x G [0, 27r), and le t s n(x) denot e th e nt h partia l su m o f it s Fourie r serie s (see 2.5.12). Sho w that i f x n i s the smalles t positiv e numbe r a t whic h sn(x) attain s it s loca l maximum , the n li m s n(xn) = L ^^dx.

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2.5. Fourie r S e r i e s

87

2 . 5 . 1 6 . Sho w t h a t fo r a ^ 0 , e2an e—

~~ n

_ 1 / 1 — i / i„ \2a

a

2

V^/ / ^

n aT T ,

^

12

Z

a7T 7

e**=

a c ao scos n nxx — — nn si n nx

,0

< X < 27T ,

+ n xaCOSnX a2

T

_ \ ( 1 _ (1 _ )nea7r^__ ^( 7T ^ a2 + n 2 n=l

_ ^ n2 '

) < X < 7T .

Find th e sum s o f th e abov e serie s whe n x = 0 2 . 5 . 1 7 . Fo r 0 < x < 2TT and a ^ O , find t h e sum s o f t h e followin g series: n si n n a a co s n x a2 + n 2 ' a2 + n 2

E

E

71=1

n=l

2 . 5 . 1 8 . Sho w t h a t O

^,

OO

\~^ / -,\n

C0SnX

n=l

Using thi s equality , sho w t h a t

SA = ?an d E n=l n =

Mn+1 ^

2 12'

l

2 . 5 . 1 9 . Suppos e / G L 1 [—7r, 7r] and a n , 6 n ar e th e Fourie r coefficient s of / . Sho w t h a t (a) i f / ( x + 7r ) = f{x) fo r x G [-7r , 0] , the n a 2 n - i = b

2n-i

=

0,

(b) i f f(x + 7r ) = —/(# ) fo r x G [—7r , 0], the n a 2 n = &2 n = 0 . 2 . 5 . 2 0 . Sho w t h a t fo r 0 < x < TT , cosx

8 v~ ^ n s i n 2 n x 2 7T ^ 4 n -l n=l

24 and s i n x = —z 4 Jinx = > 7T7

v^- ^^ cc oo ss 2z nn xx —z . T ni L=-l ' 4 n 2 - 1

2 . 5 . 2 1 . Sho w t h a t In 2 sin x

~E

cosnx

for X ^ 2 / C T

T (fceZ)

,

n=l

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Problems. 2 : Th e Lebesgu e Integra l and In 2 c o s | U ^ ( - l )

n + 1

^ ^ fo

r x^(2k

+

G Z) .

l)7r (k

n=l

2.5.22. Suppos e a 27r-periodi c functio n / i s i n L l[—7r,7r] and a are th e Fourie r coefficient s o f / . Sho w tha t fo r x G [0, 27r], [x (£/±\ *

" \-^ v

a

n,bn

^ a n s i n n x + ^ n (l - cosnx )

=

x (^-2 °r § »



2.5.23. Prov e tha t unde r th e assumption s o f th e previou s problem , oo

the serie s ^2 n converges . Us e thi s resul t t o sho w tha t ^

l^ f*

s

not a Fourie r serie s o f an y integrabl e function . 2.5.24. Prov e tha t i f / G L2[-7r,7r], the n -. o

n

r

oi

(This inequalit y i s known a s Bessel's inequality.) 2.5.25. Us e th e result s give n i n 2.5.2 2 an d 2.5.2 4 t o prov e tha t i f / G L2[—7r,7r], then fo r an y measurabl e se t A C [—7r,7r] , lim / (f(x)-s n(x))dx = 0, -^°°JA where s n denote s th e nt h partia l su m o f th e Fourie r serie s o f / . n

2.5.26. Sho w tha t i f f,g G L2[-7r,7r], the n lim / g(x)(f(x)-s

n(x))dx

=

0,

where s n denote s th e nt h partia l su m o f th e Fourie r serie s o f / . 2.5.27. Sho w tha t i f f,g G L 2[-7r,7r] an d 1

o

o

f(x) ~ ~a o + y ^ ( a n c o s n x - f b 2

n=

Io

nsinnx),

l o

g(x) ~ - a 0 + Y ^ ( an co s nx + f3 n sin nx), n=l

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2.5. Fourie r Serie s

89

then - / f(x)g(x)dx 2.5.28. Sho w tha t i f / e cients, the n °°1 b

=

-a 0a0 + y^(a nan +

L 2 [0,2TT]

/*

& n/?n)-

an d a n, 6 n ar e it s Fourie r coeffi -

27r

2.5.29. Sho w tha t i f / , g G L 1 [—7r,7r] hav e th e sam e Fourie r series , then f = g a.e . o n [—7r,7r] . 2.5.30. Us e Parseval' s formul a (a) t o su m th e serie s l ^1

E ^ 4 ' 2-

^j ( a2 + n 2 ) 2 ' ^ lv

n=l n=

y

z

>n n=

2

(a lv

+ n 2)2'

7

(b) t o comput e 7T /»7

/

T

cos6 xcb an

d/

-IT J

cos

8

xdx.

—TV

2.5.31. Sho w tha t i f / G L2[—7r,7r] an d a nybn ar e th e Fourie r coeffi cients o f / , the n th e serie s Yl \ an\+\ n\

conver

ges

71=1

2.5.32. Sho w tha t i f a 27r-periodi c functio n / i s continuousl y differ ent iable o n R , the n max \f(x) - s n(x)\ = o(n~

1 /2

).

2.5.33. Prov e th e followin g Bernstein theorem. I f / i s 27r-periodi c and satisfie s th e conditio n \f(x + h) — f(x)\ < L\h\ a wit h som e L > 0 OO

and a > 1 /2 , the n th e serie s J2 V an + ^n converges . n=l

2.5.34. Sho w tha t i f / i s 27r-periodi c an d satisfie s th e Lipschit z con dition I / O + h) - f(x)\ < L\h\ a wit h som e L > 0 an d 0 < a < 1 , OO

then th e serie s J2 (\ an\^ + \b n\^) converge s fo r (3 > n=l

2a+l'

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Problems. 2 : Th e Lebesgu e Integra l

90

2.5.35. Suppos e tha t / i s 27r-periodi c an d satisfie s th e conditio n \f(x + h) — f(x)\ < L\h\ a wit h som e positiv e L an d a. Sho w tha t if / i s o f bounde d variatio n o n [0 , 27r], the n th e serie s J ^ y ! a \ + b\ n=l

converges. 2.5.36. Giv e a n exampl e o f a continuou s an d 27r-periodi c functio n whose Fourie r serie s fail s t o converg e o n R . 2.5.37. Sho w tha t i f a 27r-periodi c functio n / i s bounded o n R , the n |s n (x)| = 0 ( l n n ) . 2.5.38. Le t L n b e th e Lebesgue constants give n b y

Ln

~^L

sin (n + \) x\

dx. n

G N.

Show tha t L n = £ In n + 0(1 ) . 2.5.39. Sho w tha t i f a 27r-periodi c functio n / i s continuou s o n R , then |s n (x)| = o(lnn) . 2.5.40. Assum e tha t / i s 27r-periodi c o n R an d / G Ll[—7r,7r]. Us e the formul a give n i n 2.5. 8 t o sho w tha t i f s0(x) + si(x ) H hs n _i(x) n (which i s called th e nth Cesaro mean of the Fourier series for f), the n crn(x) =

1 f n sin 27rn Jo sin

2 z

-nt |t

2.5.41. Sho w tha t i f / i s 27r-periodi c an d m < f(x) < M fo r al l x , then m < o~ n(x) < M fo r al l x G R an d n G N. Sho w als o tha t i f for som e n an d x w e hav e cr n(x) = M (cr n(x) = m) , the n /(x ) = M (resp. /(x ) — m ) a.e . 2.5.42. Sho w tha t i f / i s 27r-periodic , m < f(x) < M fo r al l x an d n\an\ < A, n\b

n\

< B, n

= l,2,... ,

then fo r al l value s o f n an d x , m - A - B < s n(x) oo

uous, the n li m s n(x) — f(x) uniforml y o n R . n—>oo

2.5.53. Prov e th e followin g Wiener theorem. A 27r-periodi c functio n of bounde d variatio n o n [0, 2n] i s continuou s i f an d onl y i f -. n

lim -YkJa

2 k

+

b

2

k=0.

k=l

Conclude tha t a 27r-periodi c functio n o f bounde d variatio n o n [0 , 2ir] for whic h a n = o(n~ 1 ) i s continuous . 2.5.54. Prov e tha t i f th e Fourie r serie s o f / G L1[—7r,7r] i s lacunary , that is , CO

f(x) ~ ^ ( a n f c cosn kx + b nk smn

kx),

k=i

where ! ^±±1 - > q > 1 for k = 1 , 2 , . . ., the n li m s Hfc

k—

nk

(x) — f(x) almos t

>oo

everywhere.

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2.5. Fourie r Serie s

93

2.5.55. Assum e tha t / i s 27r-periodi c o n R an d / G Lp[—7r,7r], 1 < p < oo. Prov e that th e sequenc e o f Cesaro means of the Fourie r serie s for / converge s i n th e LP norm t o / , tha t is , lim | | < r n - / | | p = li m ( f \a

n(x)

- f(x)fdxY =

0.

2.5.56. Suppos e tha t {b n} i s a monotonicall y decreasin g sequenc e oo

converging t o zero . Prov e tha t ^ b

nsmnx

i s uniforml y convergen t

n=l

on [0 , 2TT] i f an d onl y i f li m nb n = 0 . n—->oo

2.5.57. Suppos e tha t {6 n } i s a monotonicall y decreasin g sequenc e oo

converging t o zero . Prov e tha t ] P b n sinnx i s the Fourie r serie s o f a 71=1

continuous functio n i f an d onl y i f li m nb n = 0 . n—>oo

2.5.58. Suppos e tha t {b n} i s a monotonicall y decreasin g sequenc e oo

converging t o zero . Prov e tha t ^ b

n

sin nx i s the Fourie r serie s o f a

n=l

bounded functio n i f an d onl y i f nb n — 0(1). 2.5.59. Le t {a n} b e a monotonically decreasin g sequenc e convergin g to zer o an d suc h tha t a n + i < a " + ^ + 2 for n G N . Prov e tha t —+ > a 2

n=

n

co s nx

l

is th e Fourie r serie s o f a functio n nonnegativ e an d integrabl e o n [—7r,7r]. Deduc e tha t th e serie s cos E. Icosnx n

n=2

is th e Fourie r serie s o f suc h a function . (Compar e wit h th e resul t i n 2.5.23.)

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Part 2

Solutions

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http://dx.doi.org/10.1090/stml/021/03

Chapter 1

The Riemann-Stieltje s Integral

1.1. Propertie s o f th e Riemann-Stieltje s Integra l 1.1.1. Le t £ > 0 be given . B y Theore m 1 , t o sho w tha t / e TZ(a) i t suffices t o fin d a partitio n P suc h tha t

U{P,f,a)-L(P,f,a) 0 such tha t \a(x) — a(c)\ < e/2 i f | x — c | < 5. If w e tak e a partitio n P whose mes h i s les s tha n S an d suc h tha t #;_ i < c < xi fo r som e i , then U(P, / , a) - L(P , /, a) = a(xi) - a(xi_i ) < e. The sam e reasonin g ca n b e applie d t o th e case s c — a an d c = b. Clearly, J a fda = su p L(P, f, a) = 0 . 1.1.2. Le t a = x 0 < • • • < x n — b be a partitio n o f [a , 6], an d le t z G { 1, 2 , . . ., n} b e suc h tha t a^_ i < c < Xi. The n U(PJ,a)= su

p f(x)

= Mt

xE:[Xi-i,Xi]

and L(P,f,a)= in

f /(x

) = m* .

97

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Solutions. 1 : Th e Riemann-Stieltje s Integra l

98

Since / i s continuous o n [a, 6], taking partition s whos e mes h tend s to zero, w e see that sap L{P,f, a) = / ( c ).

iniU(P,f,a) =

1.1.3. Sinc e the sets Q and M\Q are dense in M, we see that L(P , /) = 0 fo r any partition P o f [a , b]. Consequently , fdx = 0.

/ Ja

On th e other han d

nn

U(P,f) =

x

x

x

Y^ i( i ~

-{b 2 - a 2 ) ,

^2 X1 -^XiXi-i >

i-i) =

i=l 2= 1 i=l

because 2xiXi-i < (xf + x 2_x). I t i s worth notin g her e tha t fdx=l-{b2-a2)

/ Ja

Indeed, takin g the sequence of partitions P n wit h x^ — a + (b — a)i/n, i = 0 , 1, . .. ,n , we see that li m U(P n,f) = hb 2 - a 2). 1.1.4. Choos e a partition P o f [—a , a] suc h tha t —a = xo < • • • < Xj-i = 0 < Xj < - - - < xn — a. Then, a s in the previous problem , w e get n_1

U(P, f) = Y^

2

a

x

x

k+ii k+i ~

x k) > —

fc=j-i

and j 2

L P

( J) =

2

~ a ^ xk{xk+i -x

k)


0. The n there are at most 2k^ subinterval s [a^-i , Xi] containin g at least on e of the rational s mentione d above . O n the other subinterval s f we hav e Mj — rrij < 1/N. Consequently ,

U(P,f)-L(PJ) 0, we take N > 2(b — a)/e. The n fo r any partition o f mesh S < £/(4/CJV) w e get, in view o f the above,

U(PJ)-L(P,f) 0 be given . Ther e i s a positiv e intege r n o such tha t 1/n < e/2 fo r n > UQ. Choos e a partition P determine d b y 0 = xo < x\ —

X2 < • • • < Xk = 1


0 be given . Ther e i s a positiv e intege r n o such tha t 1/n < e/2 fo r n > no - Choos e a partition P determine d b y 1 1 0 = x 0 < xi = — < x 2 < • • • < x n> = — n0 + 1 ° n 0 < X n' + ! < • • • < X

nt

=




1

such tha t xi — Xi-\ < e/(4no), i > 2. Then -, n

o

U(P, f) - L(P, f) - — — + T(Ml - m 2)(x, - Xi -!) 710 + 1

7^2

no—2 n

fc+i

+ ^2 ILJ

i Mi ~ mi)ixi ~

x

i-l)

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Solutions. 1 : Th e Riemann-Stieltje s Integra l

100

So, w e hav e prove d tha t / i s Riemann integrabl e o n [0,1 ] . 1.1.8. Sinc e fo r ever y partitio n P suc h tha t Xk = 0 fo r som e k w e 6

have U(P, / , a) = L(P , /, a) = 0 , w e se e tha t / fda = 0 . No w t o se e a

that li m 5(P , /) doe s not exist , conside r partition s wit h /x(P )— » 0 Ax(P)^0

and suc h tha t fo r som e fc, x^-i < 0 < #& . I f w e selec t t ^ = 0 an d £'fc G (0, arfc], then w e get £(P , /) = 0 and 5(P , /) = 1 , respectively . 1.1.9. Suppos e tha t c , a < c < 6, is a commo n poin t o f discontinuit y of / an d a. The n ther e i s £ > 0 suc h tha t fo r an y 6 > 0 ther e exis t x' an d x" suc h tha t |x ' — c\ < 5, \x" — c\ < 6, and (1) \f(x')

- f(c)\ > s, \a(x")-a(c)\>s.

Assume, contrar y t o ou r claim , tha t li

m 5(P , /) exists . I t the n

follows tha t ther e i s 5' > 0 such tha t /i(P ) < 5' implie s tha t 2

(2) \S(PJ,a)-S'(PJ,a)\l + £ ; x/P Our tas k i s no w t o sho w tha t i f a > /? , the n V ( / ; 0,1) < +oo . Le t P = { x o , x i , . . . ,x n} b e a partitio n o f [0,1 ] . Tak e n s o larg e tha t n-i/f3 < X l j a n ( j ^d |- 0 t n e p a r tition P point s 1 1 1 1 1 nV/3' ( n _ i/2)V/3 ' ( n _ i ) i / / 3 ' ' ' " ' 2 V£ ' ( 2 - 1 /2) 1 //? * Note als o tha t / i s monotoni c o n eac h interva l [ i - 1 ^ , (i — l / 2 )- 1/ ^ ] , % = 2 , 3 , . . ., n , an d [( i + l ^ ) " 1 / ^ - 1 ^ ] , z = 1 , 2 , . .. ,n - 1 . Thu s ~

nn

o

o 1

£i/(*«)-/te-i)i a suc h that y ( / ; a , a) - V ( / ; a, x') = V ( / ; z', *) < e whenever x > x' > M. Thu s

|/(x')-/(a;)| 0. a

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1.2. Function s o f Bounde d Variatio n

123

1.2.23. Indeed , suppos e tha t \f(x')-f(x")\ < [a, b]. If x r = XQ < x\ < - • • < x n = x" , the n

L\x f -x"\ fo r x',x " G

nn

^ |/(a; 0 - f(xi- x)\ < £L{ X l -

Xi

-{) = £(*" - x').

Taking th e supremu m ove r al l partition s o f [x^x" ] yield s vf(x") -

v f(x') = V(f; x' , x") < L(x" - x') .

1.2.24. B y Theore m 1 , / = p — q, wher e p an d q ar e monoton e o n [a, b]. So, th e one-side d limit s o f / exis t a t ever y poin t o f [a , b] (see, e.g., II , 1 .1 .35) . Suppose , contrar y t o ou r claim , tha t x 0 i s a poin t o f discontinuity o f / . I f f(x^) — /(XQ) = d > 0 , the n b y th e definitio n of one-side d limit s ther e i s 5 > 0 such tha t f(x) < f(xn) + - fo

rx

G (x0 - 6, x0)

f(x)>f(x$)-- fo

rx

G (x0 ,x 0 + £) .

and

Then, i f y G [/(x 0~) + d/3,/(x+ ) - d/3 ] \ {/(*) } C [/(m) , f(x 2)} \ {f(xo)} w ^ h X i G (x o — 5,x 0 ) an d X 2 G (XO,X Q + 6), ther e i s n o x G (xi,X2) suc h tha t /(x ) = y, a contradiction . I f / ( x j ) = /(x^) ^ /(xo), analogou s reasonin g ca n b e applied . Since th e derivativ e / ' enjoy s th e intermediat e valu e propert y (see, e.g. , II , 2.2.31 ) , th e othe r statemen t follow s immediately . 1.2.25. Fo r x G [a, 6], let P = { x o , x i , . . . , x n } b e a partition o f [a,x] . Since /' i s continuous on [a , 6], the results in 1.2.1 5 and in 1.1.26 imply that n x

M ) = i™ n y i i/(xfc) - /(zfc-i)i

iim y

(t)dt

= ^ mnEi//^)i(^-^-i)= f V (*)|dt.

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Solutions. 1 : The Riemann-Stieltjes Integra l

124

1.2.26. Clearly , ther e i s M > 0 such tha t |/(x) | < M fo r x € [a , b}. Moreover, fo r a = XQ < x\ < • • • < xn = 6, using the firs t mea n valu e theorem (see , e.g. , 1 .1 .26) , w e get

J2\F(Xi) - F(x^)\

da

2=1

i

da

=E i rw ^ - r w w £

f' f(t)da(t)

2=1

= X)l/te)(«( a:oo

pose tha t li m V ( / n ; a , b) = £ < -foo . Then , give n e > 0 , there i s a 71—>00

subsequence {n/ J suc h that V(f nk; a, 6) < Z+£ . Thus for any partitio n a = xo < x\ < • • • < x n = 6, n 2=1

Letting / c tend t o infinity, w e get n

£ | / ( * i ) - / ( * i - i ) | < i + e, and th e desired inequalit y follows . oo

1.2.28. Sinc e the serie s ^2 a n

an

oo

d ^ C bn are absolutel y convergent ,

n=l n=

l

given e > 0, there i s no such tha t y ^ |a n | < e an d ^

|6

n|

< e.

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1.2. Function s o f Bounde d Variatio n

125

If x / Xk, k — 1,2,..., the n ther e exist s a 8 > 0 suc h tha t ther e i s no x n wit h n < no i n (x — J, x + 8). Consequently , fo r x — 8 < y < x,

\m-f(x)\< Y, K I + £ K\ < 1 . Summin g up ,

a(x)

a(0) i

fx

= 0,

a(0) + | i

f X G ( 01, )

a(0) + l i

fz

,

= l.

1.3.8. Conside r th e functio n a(x) =

a(a) i f x

G [a,it),

a(6) i f x

G (w, &],

with a(a) < a(b). The n f{x)da{x) =

f(u)(a(b) -

a(a)) ,

which combine d wit h ou r assumptio n give s f(u) = 1 fo r u G (a , 6). Since / i s continuou s o n [a , 6], we see tha t / ( a ) = /(& ) = 1 . 1.3.9. Sinc e a = p — g, where p, g are monotonicall y increasing , i t i s enough t o sho w tha t / G H(p) i f f n £ ^GP) > n = 1 , 2 , . . ., an d / f(x)dp(x) =

li m / f

n(x)dp(x).

The unifor m convergenc e o f {/ n} mean s tha t sup \f n{x) - f(x)\ = d n >0

x£[a,b] n

. -^°°

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1.3. Furthe r Propertie s .. .

131

Thus, give n e > 0, ther e i s no suc h tha t dn(p(b) - p{a)) < - fo o

rn

> n 0.

By Theore m 1 in Sectio n 1 .1 , ther e i s a partitio n P suc h tha t U(PJno,p)-L(P,fno,p) no, rb

/ /

rb

n

I

/>6

( x ) ^ ( x ) - / /(x)dp(a: ) < / \f

n{x)-

f(x)\dp(x)

fb £ < / d ndp(x) < - . 1.3.10. Observ e that fo r x G [0,1] we have li m nx(l — x2)n = 0 , bu t n—>oo

the convergenc e i s not unifor m o n [0,1 ] an d th e resul t i n th e previou s problem canno t b e applied . W e hav e f1 n 1 lim / nx(l — x 2)ndx = li m — =

n ^ o o j 0 n-^o

o 2( n + 1 ) 2

- .

1.3.11. A s i n th e foregoin g problem , w e canno t appl y th e resul t i n 1.3.9 becaus e {x n} doe s no t converg e uniforml y o n [0,1 ] . Let a = p — q, wher e p an d q ar e monotonicall y increasin g o n [0,1]. Fo r e e (0,1 ) , w e hav e 0 < / x ndp(x) < e n(p{e)-p(0)) > Jo n

0 ^°°

and /x

Jl-s

n

dp(x) J x

n

dp(x)

> ( 1-— ) \P(1 )-P1 Consequently, lettin g n — » o o give s p{l)-p{\-)< li

m/ x n-+oo JO

n

dp(x) < li m / x

n

n

dp(x) < p(l)-p(l-e).

~*°° Jo

Since e € (0,1 ) ca n b e arbitraril y small , n

lim / x

dp(x)=p(l)-p(l-).

The sam e reasonin g ca n b e applie d t o q. Thu s lim / x

n

da(x) =

a(l)-a(l-).

n->ocJQ

1.3.12. B y assumption , fo r an y partitio n a = x$ < x\ < • • • < # m = 6, we hav e ^2 \ an(Xk) ~ OJ n(Zfc-l)| < M. k=l

Letting n — > oo , we see tha t m

^|a(xib)-a(xife-.i)| < M , fc=i

which mean s tha t a i s o f bounde d variatio n o n [a , 6]. Moreover , w e have f f(x)da n(x) -

[ f(x)da(x)\
0 , ther e i s S > 0 suc h tha t i f the mes h o f the partitio n i s less than 6, then \f(x) — f(xk)\ < e/(3M) for x G [xk-i,xk]. Consequently , b y Theore m 3 , x) ~ f(x

/

and

m

k))da(x)

( / ( •


o

n(x),

o

which show s tha t th e sequenc e {p n} decrease s t o zer o o n [a , 6]. B y the monoton e convergenc e theore m fo r th e lowe r Rieman n integra l stated i n th e las t problem , rb rb

0 < li m / f

n(x)dx




rb

(/(x ) - / n ( i ) ) + d x + / /

/ /(x)cfe < li m / Ja

f

n (x)dx

j

v)dx, n(x)

a

where th e las t equalit y follow s fro m I , 2.4.1 9 .

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1.4. Prope r Integral s

143

1.4. P r o p e r I n t e g r a l s 1.4.1. (a ) W e hav e / i ^7—r—^dz = / - ^ -d x + / - ^ -d x J0 \x-2\ + \x- 3 | J o2 x- 5 A -2 x + 5

+J\ x-i)dx + 12 J3

££z± t ^

^— 5

93 = 2 + - l n 3 - -In5 . 44 (b) Usin g th e substitutio n t = 7r/ 2 — x, w e se e tha t / sin n xdx = / cos Jo Jo Now w e sho w b y inductio n tha t (i) / %

n

xdx.

. 2 n 7 l - 3v . . . ( 2 n -Jl )T T (v 2 ny - l ) ! !T T snT xdx = i 2-4...(2rc) 2 (2n)! !2 Jo

and 2 - 4 . . . ( 2 n ) (2n)! ! Psin s i n 2 "2 n+1+1 ;xd x l 3 . . . ( 2 n + l ) ( 2 n + l ) ! ! ' Jo It i s eas y t o chec k tha t bot h formula s ar e tru e fo r n — 1. Fo r n > 1 , integration b y part s give s (2) /

In = sin ./o i

n

xdx = — / s i n o

n1 _

xdcosx

= / cosxdsin n1_ x = ( n — 1 ) / cos Jo Jo = ( n - l)/ n-2 - ( n - l)/ n.

2

x s i nn _ 2 d x

Hence n— 1 = ^n-2 n

(3) I

-

So, if ^2n

_ ( 2 n - l ) ! !T T (2n)!! 2 '

we ge t fro m (3 ) tha t 2n+2

_ 2 n + l ( 2 n - l ) ! ! 7 r _ ( 2 n + l ) ! !T T " " 2 n + 2 ' (2n) H ' 2 ~ ~ (2n + 2)! ! ' 2 "

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Solutions. 1 : Th e Riemann-Stieltje s Integra l

144

This complete s th e proof o f (1 ) . Formul a (2 ) ca n b e prove d analo gously. (c) W e hav e / |lnx|d x = — / Inxd x + / Inxdx . ee

Integrating b y parts , w e get re

2

/ |lnx|d x = 2 - - . J± e e

(d) Substitutin g t = ir — x give s / =

/^ xsin

/ 7 1r

-

0

=

x7

77

Z*

dx=

+; — cosrz ~x y

(7r — x ) s i n x 7

dx

x / 1~ r ~ ;+—c o2s— 0

fn 7rsin x / ^ xsin x x da; / 7 ^ 2~^ ~ / 7 7 7~ Jo1 + cos ^ x j + cos ^ x 01

So, 1 _

f^

7TSin

2

X 7T

i = - / ^—a x= — . 2 J 01 + cos 2 x 4 (e) W e hav e hn = / tan

2n

xd x =1 / (

Jo Jo

V

cos x

2n_2

) tan2 n ~ 2 xdx

J

= / tan xd(tanx ) - I 2n-2 = ~ Jo 2 n- 1 Consequently, on e ca n sho w b y inductio n tha t 1l hn = (-ir(~-(i-Ul---^(-ir3 5 4V 2nv

hn-2-

l

(f) W e hav e sinx -dx = / ^ -rz. -dx ( r/ 0 sin x + co s x" 7 Jo0 si s i n (n ( |f - x ) + co s (J - x ) CO S X — Sin X , 7 T 1 , \/ 2 ox = — i — In—— /o 2cos x8 2 2 (g) Observ e tha t sin"x /"" 2 cos"x n n -ax = / ——r n: ax n sin x -f cos x J sin x + cos x . 0 0

I

4

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1.4. Prope r Integral s

145

It the n follow s tha t 7T

1.4.2. Usin g th e substitution x = cost an d 1 .4. 1 (b) , we get f\l-x2)ndx = Jo J On th e other hand ,

r'\m 2n+xtdt= J o (2n+l)!

2n)!

'„. !

n\* - i

1 t

kr '

2A ; + 1

(-1)

1.4.3. Assume , fo r example , tha t f(x^) = a. W e have f(xo) = F(x 0)= h

m.

x-+x0

x — Xo

On th e other hand , usin g l'Hospital' s rule , w e get ,. F(x) hm = X—+XQ X

~ F(x Q) F'(X) h m= XQ

X

1 -+X+

h m j{x) = a. ^,x+

x

2

1.4.4. Defin e F(x) = x cos \ - 2 f* t cos \dt fo r x ^ 0 and F(0) = 0 . Then F'(x) — f(x) fo r x e R. Thu s F i s an antiderivative o f / i n the case whe n c = 0. If c ^ 0 , then a n antiderivativ e G of f woul d equa l F(x) + c\ fo r x > 0 an d F(x ) + C 2 for x < 0 , wit h som e constant s C\ and C2 - Moreover, sinc e G mus t b e continuou s a t zero , c\ = c 2 . Consequently, G'(0 ) = 0 . Thi s prove s tha t a n antiderivativ e o f / exists i f and only i f c = 0 . 1.4.5. W e will sho w tha t ^sin^ri [0 i

f x G [a^fc+i^fc-i] , fz = 0

has th e desired properties . Indeed , sinc e / i s continuous o n (0,1 ] , 7T [

i ^ - i ) " F{x 2k) =

X2k

1 ~l

7

--/ —

T

sin — dx

X2k

(2fc-l)7T -

2k J22/CT , T

.

sin tdt = - . ^

Similarly, ^(>2fc+l) - ^ ( ^ 2 / c ) = T -

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Solutions. 1 : Th e Riemann-Stieltje s Integra l

146 Now w e pu t

\oi

fx

= 0.

Calculation show s tha t F(x) = J " ^ ( C 0 S ^ + \0 i

1

)i

f x

[ x2fc+i^2fc-i], fi = 0. e

Then F'(x) — f(x) fo r x G (0,1]. Moreover , fo r x G [a^fc+i^fc-i] ?

- — i — < - ^ b^(f(b-2e))». Since

' (f(*)) pdx-> I' (f(b-s)y>dx, Jb-e

we see tha t b ir ,. , ,i ' * f(,-))Pdx>1— I (f(b-c))"d.r b - a J a ' b-a J h c(f(b-s))" >(/(&-2r))". b-a Hence 0(p) must , satisf y 0(p) > b — 2c, fo r p > po. whic h mean s I hat lim 0{p) = b. P—>OC

1.4.34. Clearly , rb

P(x)f(x)dx =

0

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Solutions. 1 : Th e Riemann-Stieltje s Integra l

158

for ever y polynomia l P. B y th e approximatio n theore m o f Weier strass (see , e.g. , II , 3.1 .33) , ther e i s a sequenc e o f polynomial s {P n} uniformly convergen t o n [a , b] t o / . Thu s b y th e resul t i n 1 .3.9 , ob pb

/ f 2(x)dx = J an

li m / P - > °° J a

n(x)f(x)dx

=

0,

which give s f(x) = 0 in [a , b\. 1.4.35. B y assumption , b

0

P{x)f(x)dx =

for an y polynomia l P o f degre e les s tha n o r equa l t o TV . Suppose , contrary t o ou r claim , tha t a < x\ < X2 < • • • < x m < 6 , m < iV, ar e all zero s o f / . No w choos e thos e point s xi x,..., Xi r wher e / change s its sign . Withou t los s o f generalit y w e ca n assum e tha t f{x) > 0 i n [a,x^], f(x) < 0 in [x^,Xi 2 ], an d s o on. Pu t r

P(x) = l[(x

lk-x).

k=l

Then P(x)f(x) > 0 in [a , b] an d P(x)f(x) > (a,xi), ( x i , x 2 ) , . . . , (x m ,6). Therefor e

0 in each o f the interval s

rb

P(x)f(x)dx > 0, / although P i s a polynomia l o f degre e les s tha n o r equa l t o iV , a contradiction. 1.4.36. Suppos e tha t / G C{[~a,a\). (a) Not e firs t that , b y assumption , [* {f(x) + f(-x))x 2ndx= r J—a

f{x)x

2n

dx+ r

J —a

/(-x)(-a;)

2n

J—a

dx

2n

dx = 0.

= 2 f f(x)x J —a

Moreover, f (fix)

J—a

+ f(-x))x 2n+1 dx =

f f(x)x J—a

J

1 2n+

dx

i

f{-x){-x)2n+1dx =

0.

J —I

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159

1.4. Prope r Integral s Thus, w e se e tha t + f(-x))xndx =

/ (f{x)

0 fo r n = 0 , 1 , 2 , . . . ,

J— a

and th e desired resul t follow s fro m 1 .4.34 . (b) Th e proo f run s a s in (a) . 1.4.37. B y the first mean valu e theore m w e get rb r f^O

b+h r fO-\-n

/ (f(x + h)- f(x))dx =

b rO

- / f(x)dix ix

/ f{x)dx

J aJ

a-\-h Ja ra rb+h

= / f(x)dx+

/

f(x)dx

Ja+h Jb

= -hf(a + 6h) + hf(b + 6'h), where # , 6' G [0,1]. It then follow s fro m th e continuity o f / tha t Urn \ [ (/( * + h) - f(x))dx =

f(b) - / ( a ) .

1.4.38. W e hav e pb+x g(x) = / f(u)du. J a+x

Thus g'(x) = f(b + x)-f(a +

x).

1.4.39. Usin g l'Hospital' s rule , w e obtai n

h

^=11^i)=1

X—*00 yJX V

X—>0 2y/x

0 —i-

=

(b) il^dt lim —— \ =

li m cos a; = 1.

(c)

J ? si n y/idt 2xsin lim — = x^Q+ X

3

x2

li m3x—

x^0+

2

3

(d) X

lim (— [ x^oo \x

a

J

0

In ^\dt) =

Q(t)

J

li m x-^o

In P{x)-]nQ(x)

= 0.

o

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Solutions. 1 : Th e Riemann-Stieltje s Integra l

160

1.4.40. Usin g l'Hospital' s rule , w e ge t (a)

,. f i r

i

x

,\

hm - — / at — hm= x^oo^lnxJo V I + t 5 / ^ ^ V l + a; 5

1 .

(b) = lim( l + sinx) 1 / x = e ,

lim [ - / ( 1 + smt)idt J because _. ln( l + sinx ) 1 hm = x->o x x-+o

cos x h m= 1 + sin x

1 .

(c) lim (\ ( x-^o+ \x 2 J

X 0

t^dt] = li m ^ = \. J x^o+ 2 2

(d) x x2 1f 2 e lim —2 In / e l dt — li m x — x-^oo x 7 0 a?-+o o 2.x J0 e * d t

2xex2 ^-oo 2 / 0 V d £ + 2xe x2

= l i m —-r~— 2-0 7

= li

m~

e x2 + 2x 2 e x2 ~

x-^oo 2e x

So li m ( ^

- f 2x 2 e x "

= 1

.

l/(x 2 )

1.4.41. I f A = \f(x 0)\ =

max{|/(x) | : x G [0,1], the n fo r p > 0,

[ imr)'" < (£*>)'" - A. On the othe r hand , th e continuit y o f / implie s that, give n e > 0, ther e is a n interva l [a,/3] C [0,1 ] suc h tha t \f(x)\ > A - e/2 fo r x G [a,/?]. Consequently,

' |/(*)lp) " > I [ l/(*)l P] > = (,4-£/2)(/?-a)

1 /p

( £V - e/2)" ) >,4-£

for sufficientl y larg e p.

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1.4. Prope r Integral s

161

1.4.42. Le t yo G [c,d\ an d e > 0 b e chose n arbitrarily . Sinc e / is uniformly continuou s o n R , ther e i s 5 > 0 such tha t l/(zi>2/l) ~ f(x2,V2)\
0 such tha t fo r x G [a, b] an d |/i | < (5, ^(x,y +

h)-/ y(x,y)\
0.

fc=0

If w e se t 2

F ( x ) = c t i + t t+ +t

+

2iV

r " ( ^ ^ "" (^j*'

then, b y th e abov e inequality , r2N /

.

,2

J.2N

F(2N)= /JO e - ' [ 1l + l !+2 i!r + -+ (2iV) v

7

^ !) d t

On th e othe r hand ,

Fm=i

fN (

t

t

2

t

2N

N

\ f

.-( 1 + _ + _ + ... + _) t f < > |; lli(=w .

Since F is continuous, th e desired resul t follow s fro m th e intermediat e value property . 1.4.47. Pu t P(x) = anxn + an _ i x n _ 1H h

a0.

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163

1.4. P r o p e r I n t e g r a l s By assumption , (P(x))2dx = /o 7

a 0 P{x)dz o

On th e othe r hand , r-l

a0

(i) a

:1

+ /c

" fc +

+ ^4 + •

1 "

ifc + 1

fc = 0 , l ,

fc + r

n+ k

^n ^n— 1

n +A ; + 1 n Observe no w tha t

a0

+ -^-4 +

/ x f c P(x)dx= ^ 7o n +/c + l and, b y assumption ,

0 fo r k

— 1, . . ., n.

Q(k) (k + l)...{n +

k + l)

,

where Q i s a polynomia l o f degre e a t mos t n. Sinc e Q{k) = 0 fo r fc=l,2,...,n, ther

e i s a constan t C suc h t h a t Q(k) = C(k-l)(k-2)...(k-n).

P u t t i n g k = 0 i n (1 ) w e se e t h a t

Jo n

v

+1 1 n

;

rc + 1

Now, multiplyin g (1 ) b y A ; -f - 1 an d nex t settin gA : = —1 , w e obtai n a 0 = ( - l ) n ( n + l ) C . So , a 0 = ( n + l ) 2 / P(x)dx,

Jo

which implie s th e desire d equality . 1.4.48. I f I(y) = J a }'{x,y)dx, the n b y 1 .4.42 , I(y) i s continuou s o n [c, d]. Thu s th e integra l o n th e left-han d sid e o f th e equalit y t o b e proved exists . Moreover , i f g(z) = I(y)dy

an

d h(z)

= I

f(x,y)dy\dx,

then g'(z) = I(z) fo r z G [c , d], an d b y 1 .4.42 , th e functio n F(x,z) = /

f(x,y)dy

is continuou s wit h respec t t o x . I t i s clea r t h a t ^(x,z) = f(x,z) i s continuous o n R . Henc e b y 1 .4.43 , /i'(2 ) = I(z). S o /i'(2: ) = g'(z) =

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Solutions. 1 : The Riemann-Stieltje s Integra l

164

I(z) fo r z G [c, d], and therefor e h(z) = g(z) + C. Sinc e h(c) — g(c) = 0, w e see tha t C = 0, whic h end s th e proof . b_ a

b

_a

0 and li m x , x =

1.4.49. Sinc e li m x , x =

b — a, the proper

integral exists . B y 1.4.48, /X

'^dx =

f x ydy\ dx=

f (

f ( f x ydx) dy

1.5. Imprope r Integral s 1.5.1. (a ) We hav e 1 /•27T -j /•27T

/

_/ »/ 7 r /

-T~ 4

Jo si

> 7 r 44 1 /

7 ~ ^=

8

n x -f- cos4 x J

/

4

rn/4 ^

_o

-

^

/ 2

Jo cos = s

T

n xx + + cos cos44 xx n

o si o si

/ 4

r

i

J0 cos

(2x) + |sin 2 (2x

( 2

0

dx_

(2x) V I + | tan 2 (2x)7 .

/.TT/ 4

Jo l

dx

1

+ ^tan 2 (2x) J- -t- 2 ^

= 2TIV 2

(b) Observ e firs t tha t r-n/2 PTT/2

/ ln(sina;)da Jo J Thus 1 />7r/ / InfsinxW Jo

/.TT/

: = / ln(cos(7r/ oJ

2

2 — x))dx = I \n{cosx)dx. o

/ 'r / 2sin2 1 x x= - / I n dx * Jo 2

i r /2

i r7T si n a; = - / I n —dx 4 J0 2

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1.5. Imprope r Integral s

165

Consequently, r 7r/2

I hi{smx)dx Jo 2

— — — In 2.

(c) W e prov e b y inductio n tha t 1 n]

oV

(

a + l)( a + 2)---( a + n + l )

For n = 0 and a > — 1 we hav e 1 f1 Jo a-\-l

0 a

! +1

Assuming th e equalit y t o hol d fo r n , w e integrat e b y part s an d get

xn+1(l-x)adx =

f

xn+1

(~^~X^1 ) dx

,x Oi + 1 Jo

n

(l-x)a+ldx

(n+1)! (a + l)( a + 2 ) . . . (a + n + l ) ( a + n + 2) ' (d) Integratin g b y part s give s i:

In= (-lnx) o

n

dx =

n (-lnx)

1 n

~ dx =

nl

n_i.

Since I\ — 1, we se e tha t 7 n = n! . (e) Th e substitutio n £ = 1 — x/n give s n

1 - (l-x/n) n , ^ ^-ct x Jo

Z* 1 l - tn , e = / dt 1 -t = [\l + t + t 2 + --- + t Jo 1 1 1 23 n

n1

- )dt

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166

Solutions. 1

: T h e R i e m a n n - S t i e l t j e s Integra l

(f) Integratin g b y part s n times , w e ge t 1

nn n x ln xdx =

1

f

/

n

lnn~lxdx

x

o

= ••

•=

(g) I f n = 1 , the n f™ f Xf^2\n — x — t an t give s ^oo

7

/,

(1 -

)

TT/2. I f n > 1 , the n th e substitutio n

/.TT/ 2

,-

9

/

2

J0 ( 1 + x ) - 7

/.TT/ 2

2

cos

" £ c o s "2 tdt = / c o s

o7

2n 2

- tdt

o

_ l - 3 . . . ( 2 n - 3 ) ix ~ 2-4...(2n-2 )'

^'

where th e las t equalit y follow s fro m 1 .4.1 (b) . (h) Th e substitutio n t = x — \ / x2 — 1 yield s

i;

dx f 2

1

2

X \JX

17

At

o ( l + ^ 2):

rdt = 1 .

(i) Observ e firs t t h a t oo

0

x

l n x Z" 1 l n x f r 52 +^ aax2- 7 - -- r—a o- « j^ = / -T 0X

00 ln x h / i— -dxa ^ ^ Z+

and t h a t b o t h integral s o n th e righ t sid e o f th e equalit y converge . Furthermore, a f°° l n x , f \nx / -7> z Tjdx = / -1 1 z3

J0 x

+a J

0x

l

f°° ln x7 -d£ + / — 2-dx

+ a2

7a

x -f a 2

7 r^x + / , r^.To ^ o ( - T T ) dt 0 x2+a2 Ja (a2/£)2 + a 2 V ^2 a

a f 21 na-ln t. dx + — — dt 2 2 2 0x + a J o^ + a a 2 In a 7rln a

In

x,

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1.5. I m p r o p e r I n t e g r a l s

167

(j) W e hav e I n a: f°°°° lnx _ 1 f°° m a + m^ J0 (xi + a^dX-^J0 ~(T^W r

hit + t 2)'

7rlna

1

4a 3 a

3

-dt

Int ;dt, 7o ( 1 + t 2)2 '

where th e las t equalit y follow s fro m (g) . Substitutin g t — t a nx give s at = co

s im(tanx)aa :

o ( 1 + *2)2^ X

p l + cos2 x m(tanx)a x Jo 2 1p = - I cos2xln(tanx)(ix , 2 Jo x = 0 (se e t h e solutio n t o (b)) . Finally , inte =/

because J 0 l n ( t a n x ) d gration b y part s give s

2

sin2 x

1

• dx 2 ta n x cos (k) Usin g th e substitutio n t = T T — x , w e se e t h a t / cos2xln(tanx)(i Jo Jo

/= /

x= 0 — /

l n ( l + cosx)(i x = / Jo Jo

== 2

x2

. *

l n ( l — cost)dt

So, b y th e symmetr y o f s i n x an d b y (b) , 21 = / l n ( l - cos Jo Jo

2

x)dx = 2 / l n ( s i n x )

d

rn/2

/ ln(sinx) ln-+ln

n ^ \x fc=l

n

n-

J\

7

\

-

>I

n^ n

)

fc=l

n - + In

Hence b y 1 .5. 3 an d 1 .5.1 (d) , lim a n—\ (lnx)

n

-*°° Jo

2

\Jo

dx — I / Inxdx ) = 2 — 1 = 1 .

)

1.5.7. W e firs t observ e tha t th e Cauch y theore m (see , II , 1 .1 .37 ) implies th e followin g criterio n fo r convergenc e o f imprope r integrals : For g : (a , b]—> R , th e imprope r integra l J bg{x)dx converge s i f an d only if, give n e > 0 , there is S > 0 such tha t

a C 29(x)dx < e whenever

a < a\ < a + 5 and a < a2 < a + S. Consequently, b y assumption , 2x rrZX

lim / t x^0+ J

a

f{t)dt = 0.

x

Clearly, w e ca n assum e tha t ther e i s a positiv e XQ such tha t / i s either positiv e o r negativ e o n (0,xo) . I f / i s positiv e o n (0 , #o) an d decreasing, the n \f(2x){2x)ax i

/

fa

< 0.

Likewise, i f / i s positive o n (0 , XQ) an d increasing , the n

l

„ ,/ x ,I

f(x)xax i fa > 0, )/(x)(2x)ax i f a < 0 .

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Solutions. 1 : Th e Riemann-Stieltje s Integra l

170

It follow s fro m th e abov e inequalitie s tha t li m / ( x ) x a + 1 = 0 . Anal ogous reasonin g ca n b e applie d i n th e cas e whe n / i s negativ e o n (0,x 0 ). 1.5.8. (a ) W e hav e f°° dx , /— =

x->o

J 2 Xn\X

., , h m m i n x — m m 2 = +oo . o

(b) Sinc e 2 sin 1 x 1 + ir 2 ~ 1

+ x 2'

the integra l converges . (c) Th e substitutio n —h\x = t give s pi poo

pi a

/ (~hix) Jo Jo Since

dx= /

poo

a

t Jo

e~ldt= /

t

a

Ji

e-tdt+ /

t

a

e'ldt.

tae~l lim —3^ - = 0 ,

the las t integra l converge s fo r al l rea l a. Moreover , sinc e tae~t lim = a t-o+ t

1 ,

the integra l J Q t ae~tdt converge s i f an d onl y i f th e integra l J 0 t adt converges, tha t is , i f an d onl y i f a > — 1. (d) A s i n (c) , J0 x

dx {-lnx)b

t-be-(l-a)tdt

a

0

It i s eas y t o chec k tha t i f a > 1 , the n th e las t integra l diverge s t o infinity fo r an y b. Sinc e fo r a < 1 pOO pOO

h l / t- be-^-a^dt = (1 - a ) 6 "1 / r e- dt, Jo Jo it follow s fro m th e solutio n t o (c ) tha t ou r integra l converge s i f an d only i f a < 1 and b < 1 .

(e) Th e divergenc e o f th e integra l follow s fro m th e inequalit y /z Jo1

o — dx > / Tydx. + x 2 su r x J o1 +r

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1.5. Imprope r Integral s

171

1.5.9. Sinc e f(t) + l / ( / ( t ) ) > 2 , we see tha t

J* f(t)g(t)dt + jT ^j|dt > 2 £ 0(*)d* . Letting x — > oo , we get th e desire d result . 1.5.10. Th e assertio n follow s immediatel y fro m th e definitio n o f a n improper integra l an d th e Cauch y theore m give n i n II , 1 .1 .37 . 1.5.11. Suppos e tha t th e integra l J a°° f(x)dx converge s an d {a n }, an > a, i s a n increasin g sequenc e divergin g t o infinity . The n n

poo pa

/ f(x)dx

pa

n

= li m / f(x)dx =^ / n=l ^

k

= li m V ^ / f(x)dx

f(x)dx. a

n-i

On th e othe r hand , i f the las t serie s converge s fo r ever y increasin g se quence {a n} divergin g t o infinity , the n th e limi t li m f f(t)dt exist s and i s equa l t o th e su m o f thi s series . If / i s nonnegative , the n th e functio n F(x) = J f(t)dt i s mono tonically increasing. Moreover , i f there is an increasing sequence {an }, an > a , divergin g t o infinit y fo r whic h th e serie s (1 ) converges , the n F i s bounded abov e b y the su m o f this series. So , the limi t li m F(x) x—>oo

exists. 1.5.12. B y the resul t i n the previou s problem , th e integra l converge s if an d onl y i f J^inTr l

+ x a s i n 2 x ~ ^Jo l

+ ( x + n7r) a sin 2 x < °°

'

Now observ e tha t o1

dx f < + ( ( n + l)7r) a sin 2 x Jo

n

dx

1

~ Jn 1

+ (x + n?r) a sin 2 dx -f (n7r) a sin2 x

Moreover, w e hav e

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Solutions. 1 : Th e Riemann-Stieltje s Integra l

172

Substituting y = tanx , w e se e tha t ^ 2 dx

dy 2

2

5

+ {b 2 + l)y2 2>/6

+ b sm x~ J 01

J/o0 l

TT"

It the n follow s tha t th e integra l converge s fo r a > 2 and diverge s fo r 0 < a< 2 . 1.5.13. No . Tak e f(x) = e~ x + g{x), x e [0 , oo), wher e

9{x)

0

if x

6 [0,7/4] ,

1

if s

= 2,3,... ,

if x

e [n — n~ 2,ri\, n

2

n {x - n) + 1 2

—n (x - n) + 1

if x G [ n , n - f n "

0

otherwise.

2

], n

= 2,3,... , = 2,3,... ,

1.5.14. Yes , i t does . Indeed , i f i t i s no t tru e tha t li m f(x) = x—>oo

0,

then ther e exis t e > 0 an d a sequenc e {x n } divergin g t o infinity , xn+i—xn > 2e, and such that f(x n) > e. B y the mean value theorem , f(x) = f(x n) + f'(£ n)(x ~

x n),

Xn < £ n < X < X n + e/4 .

Consequently, £

f(x)>e-2-

2'

and

f(x)dx > J2 / /(*)

&

* > E / f^

dx

^

o

8

-foo ,

a contradiction . 1.5.15. Assume , contrar y t o ou r claim , tha t li m f(x) = 0 doe s no t x—>oo

hold. The n ther e exist a positive number e and a n increasing sequenc e {xn} divergin g t o infinit y suc h tha t eithe r f(x n) > £ fo r al l n o r f(xn) < — £ for all n . Suppose , fo r example , tha t f{x n) > £ for al l n. By th e unifor m continuit y o f / , ther e i s 5 > 0 such tha t i f \t — s\ < e/2, an d therefor e rxn+5

(1) /

f{x)dx

> eS.

J xn — 5

On th e othe r hand , sinc e the imprope r integra l J a°° f(x)dx converges , by th e Cauch y theore m (se e 1 .5.1 0) , ther e i s a o > a suc h tha t fo r a2 > a i > ao , < eS,

f(x)dx\ i

I

CL-L

which contradict s (1 ) . Additionally, w e observ e tha t i f / i s continuou s o n [a , oo) an d lim f(x) — 0 , then / i s uniformly continuou s o n [a , oo) (see , e.g. , II , x—»oo

1.5.7(b)). It i s als o wort h notin g her e tha t th e resul t i n 1 .5.1 4 is containe d as a specia l cas e i n thi s problem . 1.5.16. Le t {x n} b e a n increasin g sequenc e divergin g t o infinity . Then, give n e > 0, ther e i s no suc h tha t /•OO

/ f(x)dx Jxno


no, pX-n POO

(xn - x

no)f(xn)


a contradiction .

(b) Le t en

an = e e , n = 0,1 ,2 , We defin e / b y settin g f(x) = a n fo r a n _i < x < a n , n = 1 , 2, Then, b y 1 .5.1 1 , oo

dx \-^ e

a n- a

~ ar, /(-) n 1 =

Je

n _i

.

because li m ^-^- — 0 . O n th e othe r hand , n—>-oo

(y, Tan dx "

dx ^__

f°° dx

xe e e " KS*J p '

E

- p'»

e—

*•

e

1 *-! O

O

-,

^1

Y

n=l n=

l

1.5.18. Se t F{x) = J* f(t)dt. The n F'(x) = / ( x ) , an d b y assump tion, lim (F'{x) + F(x)) = Z , ! G R .

X—>00

It follow s fro m II , 2.2.3 2 tha t li m F(x) = / , an d therefore , x—+oo

lim /(x ) = li m F\x) = :r—>oo x—>o

0.

o

1.5.19. Pu t F(x) — J Q f(t)dt. Then , b y assumption , F i s increasing , and integratio n b y part s give s

ir i

r i

- / xf(x)dx

=

r

- / xdF{x)

)dx.

= F{n) - - F(x

We kno w tha t li m F(n) = L f(x)dx
oo n

u

m+

n—>o

-+

o

F(n-l) < 1

T


0 such that |/(s ) — f{t)\ < 1 i f \t — s\ < 5. Now suppose , contrar y t o ou r claim, tha t / i s no t bounded . The n ther e i s a sequenc e {a n} suc h that a n + i > a n + S and \f(a n)\ > n. B y assumption ,

/ f(t)dt\

> / f(t)dt\

f(t)dt

- /

f(t)dt -M. Moreover, w e hav e \f(t) — f(a n)\ < quently,

1 for t G [a n — 5/2 yan]. Conse -

f(t)dt >(\f(an)\-l)S->(n-l)Sand

f{t)dt >{n-l)~(

M,

Ja

a contradiction . 1.5.21. Integratio n b y part s give s

(1) f

f(t)f"(t)dt = /(*)/' (x) - /(a)/'(a ) - f (/'(*)) t/a J

S

dt.

a

By th e inequalit y (/(x)) 2 + tf"{x)) 2 > 2\f(x)f"{x)\ an d b y assump tion, th e integra l J a°° f(i)f"{t)dt converges . Clearly , f*(f'(t)) 2dt ei ther converge s o r diverge s t o infinit y a s x — » oo . In th e latte r case , b y (1), li m f(x)f f(x) = +oo , an d sinc e /2(*)-/2(a)

r Ht)f(t)dt, Ja

we se e tha t li m f 2(x) = 2

x—>oo

J^°(f(x)) dx. S

+oo , whic h contradict s th e convergenc e o f

o the convergenc e o f f^°(f'(t)) 2dt i

s proved .

1.5.22. I t follow s fro m th e Cauch y theore m (se e 1 .5.1 0 ) tha t th e improper integra l J^° f(x)g(x)dx converge s if and onl y if, give n e > 0 , there i s CLQ > a suc h tha t fo r ci2 > a\ > ao,

f

f(x)g(x)dx


0 such tha t \g(x)\ < C fo r al l x G [a, oo). By (1 ) , the imprope r integra l J a f{x)dx exists, s o th e Cauch y theore m implie s tha t ther e is ao > a such tha t / f(x)dx

an

ao. Thu s G2

/ f{x)g(x)dx

)dx + l^2)|

< l5(ai ) 1,

and th e functio n x — i > l/(x a) monotonicall y tend s t o zer o a s x — • oo, the convergenc e o f J x § ^^dx follow s fro m th e Dirichle t test . (b) I f th e imprope r integra l f™ * sl"x*dx converged , the n J^° ^^dx would als o converg e (becaus e sin 2 x < | sinx|). Thi s woul d giv e (i)

If 1

cos 2x

-dx < 00 .

2/1"

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1.5. Imprope r Integral s

177

As i n (a) , on e ca n sho w tha t J^° CQ ^2xdx converges . Thi s combine d with (1 ) woul d impl y th e convergenc e o f J^° ^ , a contradiction . (c) Th e substitutio n x = yfi give s OO rC

sint dt. 2y/t

/

s'm(x2)dx = j Thus, b y (a) , th e integra l converges .

(d) On e ca n appl y th e Dirichle t tes t wit h g(x) = l/(x a) an d f(x) = esin x gm 2 X, becaus e

/

2esinx(sinx-l)

e s i n x sin(2x)dx


1 . (e) Pu t lnax g(x) = an

d f(x)

= si n a:.

Then g\x) =

In"" 1 x

(a - l n x ) < 0

for sufficientl y larg e x. Thu s g i s monotonicall y decreasin g t o zero , and th e Dirichle t tes t fo r convergenc e ca n b e applied . 1.5.25. I f J a a + T f(x)dx = 0 , the n als o J^ kT f(x)dx = 0 fo r k G N. For 6 > a put fc = [ ^ ] . Then , b y th e resul t i n 1 .4.8 , pb pb

/ f(x)dx\ = Ja \Ja+kT

—kT

pb

\ f(x)dx\ la+kT

=

\ f(x)d.

\Ja

nb-kT rb-kT pa+T

< / \f(x)\dx< JaJ

/

\f(x)\dx

= C.

a

Now the firs t statemen t i s an immediat e consequenc e o f the Dirichle t test. To prov e th e secon d statement , se t f* f(x)dx consider th e integra l

=

I ^ 0 an d

/(*) - ^ ) g{x)dx. Ja

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Solutions. 1 : Th e Riemann-Stieltje s Integra l

178

It follow s fro m wha t w e hav e alread y prove d tha t thi s integra l con verges. Consequently , J^° f(x)g(x)dx converge s i f an d onl y i f th e integral J g(x)dx converges . 1.5.26. (a ) Sinc e r27T

sm(smx)ecosxdx cos:E

= / sin(sinx)e

^+ / sin(sinx)e

JO

cosj:

(ix = 0 ,

JTT

the give n integra l converges , (b) W e hav e / sin(sinx)e JO

sm;r

(ix = / sin(sinx)e

sm:r

Jo /o

sm:r;

Gfo + / sin(sinx)e

JO

(ix

JTT

(esinx - e~ s'mx) sm(smx)dx >

0.

Thus th e integra l diverges . x

1.5.27. Observ e first tha t li m ^ x-+o+

x

— exist

+

smx

s a s a finite limi t fo r al l

positive a. S o w e ca n confin e ourselve s t o studyin g th e convergenc e of oo sinx : ax. a x + sm x We hav e 2 sin x si n x sin x a a a a x + sin x x x (x + sinx ) We kno w (se e 1 .5.24(a) ) tha t fo r a > 0 th e integra l J 2°° § ^-dx con verges. So , i t i s enoug h t o stud y th e integra l

s:

sin2 x J2 x a(xa + sinx ) dx. poo

Since '' x

2 sm 2 x sin x a a a a (x + 1 ) " " x (x + sinx) ~ x a(xa -

1 ) '

we see that integra l (1 ) converge s fo r a > 1 /2 . Applyin g th e resul t i n 1.5.25, we find that th e integra l J* 2°° w ^ + D^ diverge s f° r a — V^So, i t follow s fro m (2 ) tha t th e integra l (1 ) als o diverge s i f a < 1 /2 . For a > 1 / 2 th e integra l converges .

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1.5. Imprope r Integral s

179

1.5.28. Sinc e ,oo 1

f(x)dx= /

0/0))-cb , J aX

the assertio n follow s fro m th e Abe l tes t fo r convergenc e o f imprope r integrals (se e 1 .5.22) . 1.5.29. Assume , fo r example , tha t / i s decreasin g o n [0 , oo). Then , since f n°° f(x)dx exists , w e se e tha t li m f(x) = 0 . Hence , b y 1 .5.1 1 , />oo °

/ f(x)dx

° «(

= Y, /

n+l)/i

°

°

f(*)dx

h^2f(nh) J® n =

So,

=

h^2f(nh)-hf(0).

l n=0 0 0

POO

0 < / i V / ( n / i ) - / f(x)dx 1 , the n li m e

x

xa x

— 0, s o i t suffice s t o sho w th e conver -

gence of ^~ldx _.

r

X

/ ex with som e XQ > 0 . Sinc e li m e x /2x1a

— 0, ther e i s x$ suc h tha t

re—•oo

xa-ie-x/2


XQ . Henc e /•oo

/>co

x a l

/ e~

x - dx
1 , the n Cn+1 n

-

cn a

'

i + I'i > i ,

+ n V n

y

a

because ( l + ±) > 1 + g (see , e.g., II , 2.3.7(a)). Thu s i n this case the sequence {c n} eithe r converge s o r diverge s t o infinity . I f 0 < a < 1 , then ( l + £) a < 1 + % (see , e.g. , II , 2.3.7(b)) , an d consequently , the sequenc e {c n} i s monotonicall y decreasing . T o en d th e proo f i t is enoug h t o appl y th e resul t give n i n II , 3.3.2 1 (whic h ca n als o b e extended t o th e cas e whe n A = -hoc) .

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1.5. I m p r o p e r Integral s

181

1.5.32. W e hav e r}. a _ 1 n.!

r ( a ) = lin->oo m a (a + 1 ) . . . (a + n — 1 ) n.a—1 n.

lim ™ a ( a + l)(f + l ) . . . ( ^I + l ) a fc= = h m n1 -e

71-1

lim

a e

a/f

(lnn-(1 +i+-+^r))IF T e "

n-+oo a

,-* • \1

c

+?

1.5.33. B y 1 .5.24(a ) we know that th e integra l f 0°° ^^dx converges Therefore

.

n7r/2 / 2 r ° sin1 x, sin x , v r sinn x 7 B f /a x = li m / ax = li m / ax. n n Jo x ^°°Jo x ^°°Jo x Hence / 2 f°° sin x , , . r sin(2 n + l) x , / ax = li m / ax . n Jo ^ ->°°Jo x We wil l sho w tha t r / 2 s i n ( 2 n + l ) xT T 1/ — ^ -dx = - , n = l,2,... ,

and (2) li

mf f n ^°° \Jo

/2 x

M ^ + D x ^_ Jo

r/ » sin(2n +l), \ sin xy

=

Q

To sho w (1 ) , recal l tha t fo r x E (0, 27r), 1 sin(±(2 n + l)s ) - 4 - cos x + co s 2x + • • • + co s nx = ^——. 22 sm | Hence sin(2n + l) x ^ ^ —— = 1 + 2cos2 x + 2cos4x H + sinx

. 2cos2nx , x

x

e (0,7r) .

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Solutions. 1 : Th e Riemann-Stieltje s Integra l

182 This give s

r 7r/ 2

sin(2n - f l)x . n ax — x2 //o sin To prove (2) , observeJOtha t b y 1 .4.1 1 (a) , ^/2M2n+ sin(2 )xn + l)x , f 1

n

ton r Q x

**-TQ s

j Jo

^ ° ° V Jo x

f ' smx — x . .

= h m / sm(2 n-+oo j0 xsin

n/2

x

_

sin(2 n + l)x dx mx .

n + l)xdx = 0 .

1.5.34. I t follow s fro m th e inequalit y l_

x

2 < e - 21
ao pO rb

b' rrD

f{x,y)da x ix\ < e

/ f{x,y)dx- / J a

J a

for al l y G A. Takin g y — > yo , w e ge t b y (1 ) 6 r/»0

/.&' no

/ (p(x)dx — / (p(x)da Ja

0 be chose n arbitrarily . The n there exist s ao > a such tha t fo r a b > ao,

and

r

f(x,y)dx

f

0, there i s 770 > 0 such tha t for 0 < 77 , rjf < 77 0 pb—r) no — rjrb—r}'

no

f(x,y)dx- / / f{x,y)dx-

jf(x,y)dx

«/ a t

|< £

/a

for al l I / G A. Takin g 2 /—» yo, we get by (1 ) t>—77 pb—r}'

(p(x)dx — \ (p(x)dx

0 be chosen arbitrarily . The n ther e exist s 77 0 > 0 such that fo r an 0 oo

^ = = // (p(x)dx = 0 .

Since th e resul t i n 1 .5.4 0 ca n b e applie d t o th e integra l J 2°° e xV dx, the proo f i s complete . 1.5.55. Pu t fn(t)

{{l-^Y^-1 i I0i

f 0oo

theorem (see , e.g., II , 3.1 .1 6) , {f n} converge s to / uniforml y o n [0 , a]. Since | 0 °° f(t)dt = T(x) < o o (se e 1 .5.30) , give n e > 0 , •>o o

/•o o

/ fn(t)dt

< / f{t)dt

JaJ

< e

a

for sufficientl y larg e a. Therefor e th e resul t i n 1 .5.4 0 can b e applied . 1.5.56. W e firs t sho w tha t 1 W

2

smnx dx = n o sinx We kno w (se e (1 ) i n th e solutio n o f 1 .5.33 ) tha t (i)

I

1x12

sin(2 n + l)x , T T dx = —. sinx 2

Moreover, sinc e n-1

^sm(2k +

1 — co s 2nx 2sinx

l)x

k=0

sin nx

X ^ 0 , ±7T , ±27T, . . . ,

equality (i ) follows . Substitutin g y — nx i n (i ) give s ^ / 2 /sin V2

2

2//^

dyy = —. 2

sin(2//n)

2/

Now defin e for x

1

/nW = { ( ^ ) ( ; E & ) ^ 2

0 fo

= 0,

(Xa^mr/2 rx

> nir/2.

for x

= 0,

,

We hav e 1

lim / n ( z ) v

( ^ j fo

r x>0

,

and th e convergenc e i s unifor m o n eac h interva l [0,a] . Recal l (see , e.g., II , 2.5.28(a) ) tha t fo r 0 < x < TT/2 , smx 2 > - . X IX

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1.5. Imprope r Integral s

195

So, „ , N , ' s m x\ 7r fn{x) < [ —^j —

2



>0 ,

and since J 0°° ( ^ ^ ) dx < oo, the uniform convergenc e of J0°° f follows fro m 1 .5.35 . Hence , b y 1 .5.40 , - = li m / f I n-+ooJ

Q

n(x)dx

=

J

/ li Q

mf

n(x)dx

n(x)dx

n^oo

1.5.57. W e hav e 00 f°° x a-x , f 1 x a~l , f x*" 1 , T T / dx = / a x+ / a x= ii+i 2Jo1 +^ J o H x J 11 +x

For 0 < x < 1 , a —1 °

°

and th e serie s converge s uniforml y o n [77, 1 — 77'] , wher e 0 < 7 7 < \ — T)' < 1 . Moreover ,

0 < sn(x) = Vc-i)*^*-1 = ^ d - ( - * ) ") < ^-^ Since J Q x a~1 dx = satisfied an d

1 /a , w e se e tha t th e assumption s o f 1 .5.5 3 ar e

n=0 u

n=

0

Furthermore, th e substitutio n x = 1 /y give s r1

7|

-a r

io H y 7

l 0

7l

(l-a)-l

i+ y ~

i-

a

where th e las t equalit y follow s fro m th e above . Henc e / -, Jo1

dx= +s a

- + > (-l) Mr + v aa -f / c a f- f \ + ^

— fc/

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Solutions. 1 : Th e Riemann-Stieltje s Integra l

196

which i s th e firs t equalit y t o b e proved . T o prov e th e othe r on e w e start wit h th e identit y (see , e.g. , I , 3.8.37 )

=*n( i -

smx

n=l

Thus i f x j^ kn, k G Z, the n oo

= l ^ In In I sin £ I = I n \x\ -fn Y

Note tha t th e derive d serie s 2

^x

— n 27r2

converges uniforml y o n eac h compac t interva l disjoin t fro m th e se t {kn : k G Z}. Henc e w e ge t cosx 1 ^ 2 x COt X = = - + > —z — z -z smx x ^ x — n 7T n=l

1 + niT J

—' \ x — nil+x

x*

n=l

It the n follow s tha t tanx = — cot(x — TT/2)

£

^ \x

1

- (2n - 1 )TT/ 2 x+

+ (2 n - l)?r/ 2

Finally, usin g th e identit y 1 1 / x x\ —= - co t - + ta n - , smx 2 V 2 2 / we obtai n 1 1 sinx x

^

/

1

i

\

+ y; ( -i)M—i_ + _ i _ ), n=l x

7

which implie s th e desire d equality .

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1.5. Imprope r Integral s

197

1.5.58. W e hav e 6 ] l>oo xa-l _ -^ xb-l

Jo 1

-dx z fl x a~l -x h~l , f°° x a~x - x h~l , = I dx - f / dx Jo l x J 1 -x x -

(!/x)a-l _ ( l / x ) ^ 1

rl x a-l _ xb-l rl

~ Jo l x f1 x a~x -x~ a , = / dx

Jo l

+

dx

7 o (l-(l/x))x* f 1 x b~l -x~ b , — / — dx

~x Jo

l

~x

= Ji-/ 2. As i n th e solutio n o f th e precedin g problem , w e ge t 1

W 1 hr = ~ + > — a ^-^

\a + n a

—n

= 7 r cot 7ra.

n—l

1.5.59. (a ) Th e functio n ln(l - x) n=l

can b e continuousl y extende d t o [0,1 ) an d th e powe r serie s converge s uniformly o n each interval [0 , 6], 0 < b < 1 . Moreover, i f S n(x) denote s the nt h partia l su m o f th e series , the n \Sn(x)\ = S n(x) 1 I

/ tan Jo J

a

rl

x d x = / y a(l-y2)-%-^dy= o^ 1„ 1 fa

2V

2 2

a 1

'2

2

t%~* Jo \7

(1 - £ ) ~ ^ dt

T

/ 2cos(7ra/2)

'

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203

1.5. Imprope r Integral s where th e las t equalit y follow s fro m 1 .5.64 . (b) Sinc e

r dx

- co s x V2Jo

Jo y/3

dx

r

i

H

+ sin 2 (x/2)

the substitutio n y — sin(x/2 ) yield s

f,

dx

= v~2 f «L= = ^ f ,-3/ 4(1 _ t)-^dt \J\-y A 4

Jo V 3 - co s x Jo

J0

-—5(1/4,1/2)-—

r(3/4

)

.

Now usin g th e identit y F(a)F(l — a) = -^—, 0 < a < 1 , we se e tha t T(l/2) = v^ F an d T(3/4 ) = y/2n/(T(l/A)), whic h give s th e desire d equality. (c) A s i n (a) , w e ge t / sin"" Jo 2

1

xdx=- t*' Jo

1 2

- ^ - ty

= l -B(a/2M2) =

2

xl2

dt

a 2

- B(a/2,a/2) 1

where th e las t equalit y follow s fro m th e duplicatio n formula . 1.5.70. Ther e ar e man y proof s o f thi s formula . Her e w e presen t a proof du e t o W . Felle r [Amer . Math . Monthly , 74(1 967) , 1 223-1 225] . Put (1) A

n

= I n n\-(n + 1 /2 ) I n n + n.

Our ai m i s to sho w tha t lim A

n

= In V2TT.

n—*oo

Let &k

1

rk

rk

r

r

-Ink— lnxdx= 1 1/2 Jk-

/2

hi(k/x)dx,

1 2 Jk- 1 /2 Jk- /2 1 rk+l/2

bk = / lnxdx—-lnk Jk 2

1 rk+ /2

= J

\n(x/k)dx. k

Then

«fc — 6jf e = 1 + lnfc + Tfe — - j I n (fe — -J — ( f c + 2 ) ^ ( f c + 2 Copyright 2003 American Mathematical Society. Duplication prohibited. Please report unauth Thank You!

204

Solutions. 1 : Th e Riemann-Stieltje s Integra l

Consequently, (2) ] T ( a , e - ^ ) = n + lnn ! + - m - - (n + - j I n (n + - j = B n. oo

Now w e show tha t th e serie s ] T (ak — b k) converges . Sinc e k=l 1 , , / r l / 2-

2

(3)

ak = I n— dt an d bk = / I n (1 + t/k) dt, — 1 Jo V& Jo we se e tha t ak > bk > ak+i > 0 . Moreover , li m ak = li m bk — 0. fc—>oo fc—+00

Thus th e serie s ai - fei + a 2 - b 2 H +

a n - b n + .. .

converges b y th e Leibni z test . Thi s mean s tha t li m B n exist s an d i s n—>oo

oo

a

equal t o th e su m o f the serie s Y2 ( k — bk)- I t follow s fro m (3 ) tha t fe=i

ak-bk =

1/2 2 - / f I ( n ( t1 - — \I dt.

Thus 1 oo . /

2o o,

1

2

\

5>-«~jL EH "*)* because th e serie s o n th e right-han d sid e converge s uniforml y o n [0,1/2]. So , "1/2 a oo

oo « ! /

! > - «=

/ oo ^

f2

2\

) dt

-/ ^ ( i - p

/• 1 / 2 , sinTr t 7 -- / I n dt, Jo Kt where th e las t equalit y follow s from , e.g. , I , 3.8.37 . Usin g th e resul t in 1 .5.1 (b) , w e ge t f1/2^ sinnt 1 l n

-J0 m - ^ * = - ( m . - i ) . By (1 ) an d (2) , l i m ( A n - B n ) = li m ( n+ i ) In ( 1 + -* - j + ]• In 2 = ^ ( 1 + l n 2 ) . n—>oo n—»o

o\ Z

/V

Zn

I I

Z

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1.5. Imprope r Integral s

205

Finally, w e arrive a t lim A n = li m B n + - ( 1 + I n 2) = I n y/2n. 1.5.71. W e first not e tha t T i s infinitely differentiabl e o n (0 , oo). In deed, th e imprope r integra l f Q x a~1 \i±xe~xdx converge s uniforml y on eac h interva l [c , d], 0 < c < d, becaus e eac h o f the integral s /x

a1

~ \nxe~xdx an

d/

x

1 a

~ \nxe~xdx

converges uniforml y o n [c,d]. So , applyin g 1 .5.44 , w e see tha t />oo

1 a

~ \nxe~xdx.

r'(a)= / x Jo The formul a T(n\a)= /

a x 1 - ]nnxe-xdx Jo /o .5.655 , can b e obtaine d inductively \. Now ,, bbyy 11 .5.6 r(o)r(6) T(b)b r( T(b)-B{a,b) = r(b) r(o + b) T(a + b)

o + 6)-r(a )

r ( 6 + l ) T(a + & ) - ! » T(a + b) Letting b —» 0 + w e ge t T'(a) T(a) 6^0

lim ( r ( 6 ) - S ( a , 6 ) ) . +

Since (se e th e solutio n o f 1 .5.65 )

f

X

.6-1

B(a,b) — I — (l +——rdx, x) we obtai n

(i) m

= , im r

X

6-i1 fe-

^

^

Moreover, th e imprope r integral s

iy'{'"-(n^h r^'( e--(iT^)

dx

converge uniformly o n [0 , bo]. Thu s the result i n 1 .5.4 3 can be applied , and w e ca n switc h th e limi t an d th e integra l i n (1 ) . Thi s complete s the proof .

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206

Solutions. 1 : Th e Riemann-Stieltje s Integra l

1.5.72. (a ) W e firs t sho w tha t th e functio n = ScTjx + 1 ,2) ' T{x + l)

V

is monotonicall y increasin g fo r x > 1 . T o this end , observ e tha t (ln [X))

*

+

2x

+ 1 )-

r(x+±) T(x

By th e precedin g problem ,

rr(x (x ++1) i) r'(r ' x(x++|)\)f r°°_J__i yr+ r(x + i) r( x + i) ~y 0 (i + t)*+i'

t -1

/ o ( 1 + 0-+ 1 v T + 7 + 1 JO

< ~ /

2j0 ( 1 "

7^

r-7T *

l + t)*+ i

2a; '

;

which shows that (lnF(x)) > 0 . Consequently , F increase s on (1 , oo). So li m F(x) = li m F(n) . T o find thi s limit , w e wil l us e th e dupli cc—>oo n—->o

o

cation formul a an d th e Stirlin g formul a give n i n 1 .5.6 8 an d 1 .5.70 , respectively. Henc e lim F(n) = li m ^ ( n + 1 /2 ) = ^ ^ oo r ( n + l ) n - . o o r ( n ) r ( n + l ) 2 mf(2n-1 ) ! 2 1 n i ^ o ( n _ i)! n !2 ^-

^

1 2n

-

,. Q ^ ( 2 n - l ) 2 - -1 / 2 e - ( 2 n -1 ) = h m Pn—7^ ; r = 1 , n-oo M v / 2 n ( 2 n - 2 ) 2 r i 1- e - ( 2 n - 2 ) where {f3 n} i s a sequenc e convergin g t o 1 . (b) Not e firs t tha t i f a = 1 , then b y 1 .5.65 ,

x"B(a,x)=xB(l,x) =

X 1

^™ 1 =

1 [x 4- 1) for al l x > 0 . So , i n thi s case , th e limi t t o b e foun d i s 1 . W e wil l show tha t th e functio n F a(x) — xaB(a,x),x > 0 , i s monotonicall y

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207

1.6. Integra l Inequalitie s

increasing i f a > 1 , an d monotonicall y decreasin g i f 0 < a < 1 . W e have linear;J - ^ +

r (

^^

+

a )

00 1 1 /

_ a Z*

\

dt

+ t)x ~ {i + ty+*j J'

~x~j0 \(i If a > 1 , then r°° / I

I

\

dt _ r°° I +1 — ( i +1) 1 -^ dt 1 /•°° , a < a / T ^ x— rrdt = - ,

where th e las t inequalit y follow s fro m th e inequalit y ( 1 + t) 1 a > 1 -j - ( 1 - a)t (se e II, 2.3.7(a)) . Thi s show s tha t (\nF a{x))' > 0 , whic h means tha t F a i s increasing . Similarly , i f 0 < a < 1 , the n th e in equality ( 1 4- * )1_ 0 < 1 + ( 1 - a)t (se e II , 2.3.7(b) ) implie s tha t F a is decreasing . Consequently , t o find th e desire d limi t i t i s enoug h t o calculate li m F a(n). W e ge t n—>oo a

lim n B(a,n)= h

m -^oo r ( a + n )

naI»(n-l)! ^oo (a + n - l)( a + n - 2 ) . . . (a + l)aT(a) na~ln\ , N — hm — — -— - = r(a) , n-oo ( a + n - l)( a + rc - 2 ) . . . (a + l) a where th e las t equalit y follow s fro m 1 .5.31 .

1.6. Integra l Inequalitie s 1.6.1. I t i s clear tha t

i [la

U{X)g{V)

~ !{V)9{X))2dX) dV ~ ^

Hence 2 f f\x)dx f J aJ

g a\

2

(x)dx - 2 ( I f(x)g(x)dx) >

0,

J aJ

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208

Solutions. 1 : Th e Riemann-Stieltje s Integra l

which give s the desire d inequality . Now , i f / an d g are continuou s o n [a, b] an d th e equalit y holds , the n / (f(x)g(y)

-

f(y)g(x))

2

dx = 0

Ja

for ever y y G [a, b]. Consequently, f(x)g(y) — f(y)g{x) = 0 fo r ever y x G [a, b] an d y G [a, 6]. So if there i s a yo G [a, 6] such tha t g(yo) ^ 0 , then f(x) — ( \g(x). I f g i s identicall y zer o o n [a , 6], the n w e ca n take A i = 0 and A 2 = 1 . 1.6.2. I t i s a n immediat e consequenc e o f the Schwar z inequality . 1.6.3. B y th e Schwar z inequality , 9

(b Moreover, sinc e

(f(x)-m)(f(x)-M) „ ^ - ^ ;;

r

V
0

J f (x)dx-(J f(x) Jo V o

On th e othe :rr hand hand , D(f, f) = (M i - F)(F -

mi

)-

[ (M i - f(x))(f(x) Jo

mi)dx ,

which implie s tha t D(f,f) -

feAj0 ~

IT

.

The infimu m i s equa l t o 4/-7 T and i s attaine d fo r f(x) = ^aXx

2

)'

1.6.7. Th e inequalit y follow s fro m

(M-f(x))(f(x)-m)dx>0. 1.6.8. Se t

F(t)=^f(x)dx)j -j\f(*)Y

dx, i e [ 0 , l ]

.

Then F\t) =

f(t)(2J*f(x)dx-(f(t))

2

y

and, i f G(t) = 2f*f(x)dx-(f(t)) 2, the n G'{t) = 2f(t)(l-f'(t)) > 0. Consequently, G(t) > G(0 ) = 0 , whic h give s F'(t) > 0 . So , F(t ) > 0 and, i n particular , F(l) > 0. Moreover, i f F ( l ) = 0 , the n F(t) = 0 fo r t e [0,1 ] , an d therefor e F'(t) = f(t)G(t) = 0 . This , in turn, implie s G'{t) = 2f{t)(l-f(t)) = Oand 1 - / ' ( * ) = 0 forte (0,1 ) . 1.6.9. I t follow s fro m th e solutio n o f 1 .2.2 2 that th e functio n 1 g{x) = f(t)dt x— a is monotonicall y increasin g o n (a , 6]. Thu s g(x) < g(b). A s i n th e solution o f 1 .2.22 , one ca n sho w tha t th e functio n rb

o-x J

x

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1.6. Integra l Inequalitie s

211

is monotonicall y increasin g o n [a , 6), and therefor e h(a) < h(x). 1.6.10. Assum e first tha t bot h th e function s ar e monoton e i n th e same sense . W e hav e

f n\f(x)g(x)

-

f(x)g(y))dx) dy

pb pb

= (b-a) /

pb

f(x)g(x)dx -

/ f{x)dx /

Ja Ja

g(x)dx

Ja

and

J (j

aU(y)g{y)-f{y)g(x))dx\dy pb pb

pb

= (b-a) f(x)g(x)dx-

f(x)dx

JaJ

g(x)dx.

aJ

a

Therefore pb pb

(b-a) /

pb

f{x)g(x)dx -

/ f(x)dx /

Ja Ja

= \f a ( /

g(x)dx

Ja 6

( / W - f{y)){g{x) - g{y))dx\ dy > 0,

because, b y assumption , (f(x) — f(y))(g(x) —

g{y)) > 0 for al l x an d

1.6.11. Th e proo f i s analogou s t o tha t o f 1 .6.1 0 . 1.6.12. B y th e Chebyshe v inequalit y (se e 1 .6.1 0) , pa -

/ f(a Jo a

i pa

pa

— x)g(x)dx < - f(a J0 7

— x)dx I g{x)dx o

= - / f(x)dx «7o Jo

/

g(x)dx

< / f(x)g(x)dx. Jo 1.6.13. I t i s enoug h t o appl y th e generalize d Chebyshe v inequalit y (see 1 .6.1 1 ) wit h p(x) = q 2{x), f(x) — x an d g{x) = l/(q(x)).

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Solutions. 1 : Th e Riemann-Stieltje s Integra l

212

1.6.14. B y th e convexit y o f / , w e get / f(x)dx =

(b — a) / ( (

Ja

l — x)a + xb)dx

JO

jr^'-^m

1.6.15. Le t f(x) = ^ , x > 0 . Sinc e f"{x) = (21 n x - 3)/x 3 , w e se e that / i s strictly conve x on (e 3 / 2 , oo) and strictl y concav e o n (0 , e3//2 ). Hence i f y > x > e 3 / 2 , w e hav e 1 Tlnt

AV

2 ;

y - x j

x

^ In

t

2

y- In 2 x In 2(2/-x) L

G '

which gives A L < G A. Analogou s reasonin g ca n b e use d t o sho w tha t AL>GA i f 0 < x < y < e 3 / 2 . 1.6.16. Le t c G [a , 6] b e suc h tha t f(c) = ma x / ( # ) . Then , b y x£[a,b]

assumption, nb

rC

rb

/ f(x)dx — \ f(x)dx + / f(x)dx Ja

Ja

Jc

= (c — a) / f((l — x)a + xc)dx Jo + (b-c) f((l-x)c Jo

+

xb)dx

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1.6. Integra l Inequalitie s

213

a) f

>{c-a) ((l-x)f(a)+xf(c))dx Jo + (b-c)J «l-x)f(c)

+

Jo

xf(b))dx

>l(b-a)f(c). 1.6.17. Integratin g b y parts yield s fag(x)f'(x)dx+ f Jo /O Jo

g'(x)f(x)dx ^0

= g(x)f(x)\ aQ- [

a g'(x)f(x)dx+ f Jo Jo

g'(x)f(x)dx

= f(a)g(a) + f g'(x)f(x)dx Ja

> f(a)g(a) + f g'{x)f{a)dx =

f(a)g(b).

Ja

The case o f equality follow s immediatel y fro m th e above . 1.6.18. Substitutin g u = f~ l(t) an fX Pf(x)

d integrating b y parts give s

pX

/ f(t)dt+ / f-\t)dt=

Jo Jo

Jo

rX

/

f(t)dt+ / uf'(u)du

Jo = xf(x).

1.6.19. Assum e firs t tha t f(a) yr\y) -(y-

{y) = &/ _1 (y) = ba.

l

b)r

1.6.20. Applyin g th e Youn g inequalit y wit h f(x) = ln( l + x), we get pa pb

/ ln( l + x)dx + / (e Jo Jo which give s th e desire d inequality .

x

- l)dx > ab,

1.6.21. I f there is xo such that g~ l{x$) > f(xo), the n by assumption , xog^ixo)^ /

/

f{x)dx+ Jo Jo

g(x)dx

r^o

< / g~ Jo Jo =x

1 0g"

pg~ l

(x0)

{x)dx + / g(x)dx

(x0),

where th e las t equalit y follow s fro m 1 .6.1 8 . A contradiction . 1.6.22. I t follow s fro m th e Schwar z inequalit y tha t i f / G A, the n (2 + 36) 2 = (f f(x){x

+ b)dxj
ma x —i2 , — = 12. bem 3b + 3 6 + 1

The equalit y i s attaine d a t f(x) = 6x

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1.6. Integra l Inequalitie s

215

1.6.23. Le t / G A. The n b y th e Schwar z inequality , (1) (J

( 1 - x)f'(x)dx)
- 1,

XX

which implie s tha t f{x)>l —

x. Likewise .

f(x) - /(2 ) /(x x-2 x-

)- 1 2

r(^2) < i,

which give s f(x) > x — 1 . Consequently , /(x ) > | x — 1 | . Thu s / f{x)dx> 7o Jo

[

\x-l\dx =

1.

Since / i s continuous, th e equalit y hold s i f and onl y i f f(x) = \x — 1 | , x G [0,2] . Bu t thi s functio n i s no t differen t iable a t x — 1 . S o th e answer t o ou r questio n i s no. 1.6.25. B y th e mea n valu e theorem , f(x) = f'(0 1 )(x-a) an

d f(x)

= f'(9

2)(x-b).

If M = ma x |/'(:r ) |, the n xG[a,6]

|/0r)| < M ( a ; - a ) an

d \f(x)\ ° > t h en I baty f^ dz = J a + f{ z)dz < J a f(x)dx. I f y < 0 , analogou s reasonin g ca n b e ap plied. Assum e now that / i s an arbitrary continuou s function , an d se t I rX-\-h A 0*0 2h Jx-h 1 /(01 ^ - I t follow s fro m wha t w e hav e prove d tha t 7 Jrab fh{x)dx < J a \f(x)\dx. Moreover , w e hav e -i px+h

- 1 px+h

\h(x)\ = r r / f(t)dt\