Die Grundlehren der mathematischen Wissenschaften in Einzeldarstellungen mit besonderer Berucksichtigung der Anwendungsgebiete Band 167 Herausgegeben von J. L. Doob . A. Grothendieck . E. Heinz· F. Hirzebruch E. Hopf . H. Hopf . W. Maak . S. MacLane . W. Magnus M. M. Postnikov . F. K. Schmidt . D. S. Scott . K. Stein Geschiiftsfuhrende H erausgeber B. Eckmann und B. L. van der Waerden K. Chandrasekharan Arithmetical Functions Springer-Verlag Berlin Heidelberg New York 1970 Prof. Dr. K. Chandrasekharan Eidgenossische Technische Hochschule Zurich Geschiiftsfiihrende Herausgeber: Prof. Dr. B. Eckmann Eidgenossische Technische Hochschule Zurich Prof. Dr. B. L. van der Waerden Mathematisches Institut dec Universitiit Zurich This work is subject to copyright. All rights are reserved, whether the whole or part of the material is concerned, specifically those of translation, reprinting. re-use of illustrations, broadcasting, reproduction by photocopying machine or similar means, and storage in data banks. Under § 54 of the German Copyright Law where copies are made for other than private use. a fee is payable to the publisher, the amount of the fee to be determined by agreement with the publisher. ISBN 978-3-642-50028-2 ISBN 978-3-642-50026-8 (eBook) DOI 10.1007/978-3-642-50026-8 © by Springer·Verlag Berlin' Heidelberg 1970. Library of Congress Catalog Card Number 72-102384. Title No. 5150. For Sarada Preface The plan of this book had its inception in a course of lectures on arithmetical functions given by me in the summer of 1964 at the Forschungsinstitut fUr Mathematik of the Swiss Federal Institute of Technology, Zurich, at the invitation of Professor Beno Eckmann. My Introduction to Analytic Number Theory has appeared in the meanwhile, and this book may be looked upon as a sequel. It presupposes only a modicum of acquaintance with analysis and number theory. The arithmetical functions considered here are those associated with the distribution of prime numbers, as well as the partition function and the divisor function. Some of the problems posed by their asymptotic behaviour form the theme. They afford a glimpse of the variety of analytical methods used in the theory, and of the variety of problems that await solution. I owe a debt of gratitude to Professor Carl Ludwig Siegel, who has read the book in manuscript and given me the benefit of his criticism. I have improved the text in several places in response to his comments. I must thank Professor Raghavan Narasimhan for many stimulating discussions, and Mr. Henri Joris for the valuable assistance he has given me in checking the manuscript and correcting the proofs. July 1970 K. Chandrasekharan Contents Chapter I The prime number theorem and Selberg's method § 1. Selberg's fonnula . . . . . . 1 § 2. A variant of Selberg's formula 6 § 3. Wirsing's inequality . . . . . 12 § 4. The prime number theorem. . 17 § 5. The order of magnitude of the divisor function 19 Notes on Chapter I ........... . 21 Chapter II The zeta-Junction of Riemann § 1. The functional equation . . . . . . 28 § 2. The Riemann-von Mangoldt formula. 33 § 3. The entire function ~ . 40 § 4. Hardy's theorem . . 45 § 5. Hamburger's theorem 51 Notes on Chapter II ... 54 Chapter III Littlewood's theorem and Weyl's method § 1. Zero-free region of (. . . . . . . . . . . . . . 58 § 2. Weyl's inequality . . . . . . . . . . . . . . . 60 § 3. Some results of Hardy and Littlewood and of Weyl 69 § 4. Littlewood's theorem. . . . . . . . 73 § 5. Applications of Littlewood's theorem 78 Notes on Chapter III ..... 84 Chapter IV Vinogradov's method § 1. A refinement of Littlewood's theorem 88 § 2. An outline of the method. . . . . 88 § 3. Vinogradov's mean-value theorem. . 90 § 4. Vinogradov's inequality . . . . . . 99 § 5. Estimation of sections of ((s) in the critical strip. 106 1 Chandrasekharan, Arithmetical Functions x Contents § 6. Chudakov's theorem. . 108 § 7. Approximation of n(x) . 110 Notes on Chapter IV .... 110 Chapter V Theorems of Hoheisel and of Ingham § 1. The difference between consecutive primes . . 112 § 2. Landau's formula for the Chebyshev function '" 113 § 3. Hoheisel's theorem . 124 § 4. Two auxiliary lemmas . . . . . . . . 126 § 5. Ingham's theorem. . . . . . . . . . 130 § 6. An application of Chudakov's theorem. 138 Notes on Chapter V .......... . 139 Chapter VI Dirichlet's L-functions and Siegefs theorem § 1. Characters and L-functions . 143 § 2. Zeros of L-functions. . . . . . . 145 § 3. Proper characters . . . . . . . . 146 § 4. The functional equation of L(s, X) . 149 § 5. Siegel's theorem. 155 Notes on Chapter VI. ....... . 164 Chapter VII Theorems of Hardy-Ramanujan and of Rademacher on the partition function § 1. The partition function 166 § 2. A simple case. . . . . . . . . . . . . . 166 § 3. A bound for p(n) . . . . . . . . . . . . 169 § 4. A property of the generating function of p(n) 170 § 5. The Dedekind 1/-function .... 174 § 6. The Hardy-Ramanujan formula . 178 § 7. Rademacher's identity 185 Notes on Chapter VII . . . . . . . 191 Chapter VIII Dirichlet's divisor problem § 1. The average order of the divisor function. 194 § 2. An application of Perron's formula . . . 195 § 3. An auxiliary function . . . . . . . . . 198 § 4. An identity involving the divisor function. 200 § 5. Voronoi's theorem .......... . 202 Contents XI § 6. A theorem of A. S. Besicovitch . . . . 204 § 7. Theorems of Hardy and of Ingham .. 205 § 8. Equiconvergence theorems of A. Zygmund 209 § 9. The Voronoi identity. 223 Notes on Chapter VIII. 226 A list of books 229 Subject index . 230 I' Chapter I The prime number theorem and Selberg's method § 1. Selberg's formula. Let n(x) denote, for any real x, the number of primes not exceeding x. The prime number theorem is the assertion that (~)= lim 1. (1) x~oo x/logx A fundamental formula discovered by Atle Selberg has made a proof of (1) possible without the use of the properties of the zeta-function of Riemann, and without the use of the theory of functions of a complex variable. We shall prove Selberg's formula in this chapter, and indicate some of its consequences. We shall also prove an inequality due to E. Wirsing, which, when combined with a variant of Selberg's formula, gives a proof of the prime number theorem. We recall the definitions and simple properties of a number of well-known arithmetical functions. An arithmetical function is any complex-valued function defined on the set of all positive integers. We shall be concerned, almost always, with integer-valued arithmetical functions. The Mobius function fJ. is defined, for any positive integer n, by the following three properties: (i) fJ.(1)= 1; (ii) fJ.(n) = ( -It, if n is a product of k different primes; (iii) fJ.(n)=O, if n is divisible by a square different from l. As a simple consequence of the definition, we have l, if n= 1, I fJ.(d) = { . (2) 0, If n> 1 , dill where the summation is over all the positive divisors d of n. There are two elementary inversion formulas governing the Mobius function: 2 I The prime number theorem and Selberg's method (The first Mobius inversion formula). If f is an arithmetical function, and g(n) = IJ(d) , din then (3) and conversely. (The second Mobius inversion formula). If f is a function defined for x~ 1, and then L (~), ~ f(x) = J1(n)g for x 1, (4) n~x n and conversely. If we set f(x) = 1, f(x)=x, f(x)=xlogx, f(x)=xlog2 x, in formula (4), and note that L ~ +O(~), = logx+'Y (5) n x n~x where 'Y is Euler's constant, while n x) L -log- = _1l og2X+C +0 (l-Og- , 1 n~x n 2 x (6) x I log - = O(x) , n n~x where C and C2 are constants, we successively obtain the following 1 estimates: L J1(n) = 0(1) , L -J1I(n)o g-x =0(1), I -J1l(no) g2x- = 2Iogx+0(1), n~x n n::;:;x n n n~x n n (7) and (8)
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