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English Pages 885 [464] Year 1996
Progress in Mathematics
Analytic | Number Theory Proceedings of a Conference in Honor of Heini Halberstam Volume 2 = Bruce C. Berndt Harold G. Diamond Adolf J. Hildebrand Editors
Cs (at :
aS
Birkhauser
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FLORIDA STATE UNIVERSITY LIBRARIES
JUL 15 1997 TALLAHASSEE, FLORIDA
Progress in Mathematics Volume 139
Series Editors
Hyman Bass Joseph Oesterlé Alan Weinstein
Analytic Number Theory Volume 2
Proceedings of a Conference In Honor of Heini Halberstam
Bruce C. Berndt Harold G. Diamond Adolf J. Hildebrand Editors
Birkhduser Boston ¢ Basel ¢ Berlin
Bruce C. Berndt
Harold G. Diamond Adolf J. Hildebrand Department of Mathematics University of Illinois Urbana, IL 61801
Se} Q f pee CYT | A
7
4B6
[99 CG Vv. ae )
Printed on acid-free paper Se
© 1996 Birkhauser Boston
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ip
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ISBN 0-8176-3932-2 SET ISBN 3-7643-3932-2 SET
Contents
of Volume
Pontents Ot Volumes) trian Goes eet taeents PCAC
ee
cert
erin
et
ed cic PO Ce
LASh Ol; PAT AGIAN.
4
ck
Me Um Se
NEY COIN WEGNER Ride gedl cyt Acai chia
ato
2
CR
VO
ee,
CP OGY
occ tas
oto
hea
dak peo
bas ix
Teer hee carne renee
a Rae
og
I
Pe
xi xiii
451
Cas cen evens RoeniCks 465
PEL a te cee ee Ook Matis si. sinensis in oes hice eecw ate ik eee On an elementary inequality in the theory of Diophantine approximation
Ju DOES sls Bird Fs RON ae eg ergael ACR keg ee The integer points close to a curve II Me JUtilas..
BD, vii
Mee oi
Alte ARE Ce Cacti wissen e Dances
|W RFS 8 Coe Sl Se gee ae Cee Ck a a An estimate for Heilbronn’s exponential sum Wes Ere liam ere a Pies ere PIPES On B3 sequences
POR SE
eee nce ee
eee
471
neta 487
s eee er, ee ea Te LOM IR eee sis. orn Taek The fourth moment of Riemann’s zeta-function and the additive divisor problem
Ife, Ju IeUNEPARN AVG As ANEIVE? ot.3c:cn0.0 Bag b OOo Oe oTeee Oe ae On the uniform distribution of Gauss sums and Jacobi sums
yes 517
eo our 537
WG, INGE LRG) KOnA eee nen aon Ae eS an Oe OA ae eee Manne ee eR mere ens 559 A problem of Steinhaus: Can all placements of a planar set contain exactly one lattice point?
ee
RAE PARE? SALAAM OSes SSG CN es ie A note on the Riemann-Roch Theorem for function fields
SEs
567
Jos LencugenoVe ea EVAN Ree on oerae aoe eae Oeiac cic ke cn ea RE Or ere Catto, cca Sil Estimation of exponential sums over primes in short in-
tervals IT
Le? Liteht ameeniw reCueicatintn. estos ae eee, Weighted Wiener-Lévy theorems
PE) ae
ERE
Se es 607
NY VERTPoy 8 winborers A Gud Ginbag oir REPT COAG OD.OO LE ata Rae CETORem e oe te Spectral mean-values of automorphic L-functions at spe-
621
cial points jis USPS Ris 8 Bele. ie Soi ST aR
eeDR EO re RN eee Cre The size of the coefficients of cyclotomic polynomials
a
633
Contents
vl
Volume 2
econo Uadnut ToueoDdGomo asd oor mine GaN V Toire)akekaliners ears cin Oo On Kuznetsov’s trace formulae
641
an err 669 M. Re Murtynd CoS. Rajan .....00. oe, eens oes 8 ae Stronger multiplicity one theorems for forms of general type on GL2 Me Naircand AS Perelli.) ac cecrsarse it eaitatietrior shelter eleieie kien taee Rees 685 A sieve fundamental lemma for polynomials in two vari-
ables Ce Pomerance sas oo Ss easatpeneeevorsctask vn see ee ade tea Multiplicative independence for random integers Ri As Rankines aciig cvoaiscn orotate, oe si oreseaeay sees oe PERER On certain meromorphic modular forms
e
osioe ons703
eceeatemt ys kotor (Als)
Bs Scour fel deck a080 te Soros grratteocud sone ei eens pot oe enor iee ice Rae te chee 723 Comparison of two dissimilar sums involving the largest prime factor of an integer
HY Mie Stark occ. eas cs.sis,x-cls. obo 3 SB aneertar de Se:
Aeron aR
eee
eee con
On the determination of an L-function from one value Ky Bi Stolarskyaean ace gai Shoes we atone ee aeeae IO ee oy ise An approximation to the q-analogue ofn involving the n-analogue of a golden number
Re Gy Vallig Rani nee eta timtantan aay SA. clk es eA Small values of Dirichlet L-functions at 1
aE
oe 745
cess csS
eet ean eee Saeco ONS Global zeta functions over number fields and function fields
755
BBVA, isidscecest cede Seuesint oars
767
RES VNONDS Gace atckc) date pela ora Sosa ste Sak rere eT Consequences from the study of concentration functions on shifted twin primes
CE
SB.
WOOLEY ar creearil cases ofits atcdayn sve «:otsgstoiveas Ser ete ee An affine slicing approach to certain paucity problems
803
DO,
BaD
817
he ys eas ea RRL eee a Ramanujan’s class invariants, Kronecker’s limit formula
and modular equations (II) WB
Zhang $i
0d oa
ees oe ee, Probabilistic number theory in additive arithmetic semigroups I
839
Contents
Pee AIS
of Volume
1
eee ey pO CEs ah Sm Rene rae mma ee Weighted partition identities and applications
ae
care.
aed Dye TITERS5 Re ER gn any, hla UN” a rt ee mR Al ate tarae ee Rogers-Ramanujan polynomials for modulus 6
Bee
Hes
ee tee Soe ME Be eee NT SO On subset-sum-distinct sequences
SoM
oe Lee
ile
care eee 31
dket ANG ge Haraairectarrrcs aire con tener: oo sae oleae 39 The Brun-Titchmarsh Theorem on average
oe
MLS DATION SUG wie WOTay aces oer ie eee one otis Reamer trator 105 Congruences for Fourier coefficients of half-integral weight modular forms and special values of L-functions
teed 8g Sy NTS Teh ek Dt 8 OP es Be I Sia i fn a as a The asymptotic formula for the number of representations of an integer as a sum of five squares
129
UE BTS vey AN Yo A Sag To)Vg 0 eens een Meee eee et eee ee eee Distribution of the error term for the number of lattice points inside a shifted ball
eee 141
INPREIS OSG COU epee pete chee rt ete aeseeeee cee oye a eg, gucrai'e re testederesevsncunveleteeuetnvaeioeon OS 155 A probabilistic generalization of the Riemann zeta function JD). BOMe INNIS SidSome eae
Rome Oe eias Cee ee cre Mee Seema e mame 163 A general Heine transformation and symmetric polynomials of Rogers
DD SISTAGleye ck ane ceminmace pels Nears A sieve auxiliary function
ate As cone
ote
cs
DAC OCHIARE Ais cashesorsSes PAL ects On eae este oe oe be See Bounds on complete exponential sums
oe
as wath ee
Ue So Cotibes oetee itenetam ia ada. tiem eer axial 20-0 5 Shrne le wees A note on the fourth power moment of the Riemann zeta-function
ad 173
Lae
kN
211
Die225
Ete DAD Gussie eee eto nico tae cieic ase peestreh bc GG Re Manuine ee nen eree 231 Effective estimates of exponential sums over primes
(BL BPS EVa(re eeiest ety teh nee a nar earn eee = or ee ee ee ee Se eee 245 On products of multiplicative functions of absolute value at most 1 which are composed with linear functions
viii
Contents
Volume
H: G; Diamond; H: Halbétstam, and HB tienert.. 5. i..k csv een tes Combinatorial sieves of dimension exceeding one II 1D: Bichhornrangt he One -sere tris eek ae ieee Congruences for partition functions
P.DVTCA. EIGtt. scoetacashengn bate ooa bed Fractional power large sieves Po EES
acs oieenecanes Bros gpeve Gt
eve
iN
ae
eette
OR
eee
Man
265
rate tote 309
Debits. 323
Ot ELUTE POG EM as Olek 333
Some problems I presented or planned to present in my short talk . P. Erdos, S: W. Graham, As ivic-and’C. Pomerance suret¢ On the number of divisors of n! RES VaMns 5.285 Sok Recess ts corecetotayaves eee eye ere Generalized Lambert series M, Pilaseta;qgsas:
LR
ene atedsa
mcs cao re
eT
337 357
yh dvtend aie una toute Gay Aare RR Selia-a.ts 371 A generalization of an irreducibility theorem of I. Schur
Mie Tao Hlanive Boch). WOOUS mn cot. je secre aiindata ae eek Small values of indefinite binary quadratic forms See CICOLATAb Rene EL aLWATHOG DORON ee NOR he ooh
SH EME UP RV ZH OO SEH SEH QEAPPOUP PNOMENEQOORY
List of Participants
a
Kovacs (Univ. of Illinois) . Laporta (Univ. of Toronto) Li (Purdue Univ.) Lou (Halifax) . Luo (MSRI) Martin (Univ. of Michigan) Meyer (Univ. of Illinois) Morée (Macquarie Univ.) Motohashi (Nihon Univ.) Murty (McGill Univ.) . Nathanson (Lehman College) M. Nicolas (Université Lyon I) Peral (Univ. del Pais Vasco) . Philipp (Univ. of Illinois) Pomerance (Univ. of Georgia)
Prather (Lexington, KY) Ream (Univ. of Colorado) Reti (Univ. of Florida) Robins (Univ. of North. Colorado) Scourfield (Royal Holloway Coll.) Shiu (Loughborouh Univ.) Skinner (Princeton Univ.) CS Be eee po, jm Se etic eee aot ee ae Uae ay Srinivasan (Univ. of Georgia) =— Stark (MSRI) Stolarsky (Univ. of Illinois) Thunder (Northern Ill. Univ.) C. Vaughan (Imperial College) Walling (Univ. of Colorado) Wan (Univ. of Nevada) . Wijsmuller (La Salle Univ.) Wolke (Univ. Freiburg) Wooley (Univ. of Michigan) C. Zhang (Southw. Miss. St. Univ.) PTAA AEN eae Zheng (Zhongshan Univ.)
Kwok (Univ. of Illinois) (Univ. of Illinois) Li (Univ. of Georgia) Lucht (TU Clausthal) Maier (Univ. of Ulm) Methfessel (Univ. of Waterloo)
1, we note that the last two terms in these are essentially the same, while the first and second terms in the former are, respectively, better and worse than the second and first terms in the latter. Thus there are occasions when Theorem 1 is superior to Lemma 1. In the third application of this alternative technique to our problem it is necessary to use a refined version of Theorem 1 that depends on a more precise form of (11). 5. Approximating rationals having kth power denominators — preliminary analysis of the problem The genesis of the investigation is the introduction of two sums of the type Nw(¢,y) that count the number of positive integers m not exceeding y for which there is an integer @ satisfying the conditions
(12)
nr Al Ready,
(Cran) = 1,
where it will be assumed throughout that k > 2. First, for each of the infinitely many rational approximations p/q in lowest terms to the given irrational number @ for which
(13)
| — p/q| < 1/4?
and q is sufficiently large, we choose a large number x and a number v = v(z) such that
(14)
Qua" =q"
and
(15)
F — ea)
or) |lah > =e Aer y a
where the right-hand sides of the inequalities are not less than 1 by (21), we must allow for the additional term 1(k-1),.4(k—2) [2 r4 O | ——__—_——_ (
va
i:
which will induce an extra contribution of
,) (“—k a /
)
/
a
1/K’'
oe
ya
yl/2K
to M,—1(2u, 2v;m*p/q) and thus one of
pit(k-2)/2K+6
(31) to a
O (Soa) re
In the opposite case where both inequalities in (30) are negated, we analyze separately the situations in which ks y2
(32)
tk Tie
aocis L2il or |n| $< —,
initially considering in the first case the influence of any 7 for which
(33)
&
nie 20..
Then, for such a value of 7, any extra term of type (28) is 1k
G2
pv20
which by way of (8) leads to a donation of
pK rR “1p bee
(34)
ON.
a | eee ea V20
ie
i
rae
pi-2k/K gh/K+
=a
\eeominke a7
484
C. HOOLEY
to My_1(2, 20; m*p/q).
But, if (29) hold when m < a/p < q, then (u,q)
and (w,q) have a common value e dividing g. Hence, setting u = eu’, w = ew’, where (u’,q/e) = (w’,q/e) = 1, we have pm*u' = w', mod q/e, through which congruence a given pair u, w determines m*, mod q/e, and hence corresponds to at most O (K(a/e)) =U (K(9)) incongruent values ofm, mod q/e and thus to at most O (ek#(9)) values of m not exceeding x/y. Thus, since the number of appropriate m that answer to all pairs in (29) such that 0 < u < p; and 0 < |w| < p2 is therefore
O
ke)
Se
elg.
s
|= @
RO
pp»
0 Gant
In this case our construction reduces to that of Bambah and Chowla. The general statements of the theorems follow. Theorem 1 deals with the case n = 2, and Theorem 2 with the cases n > 3. In Theorem 3 we take n = 2, and restrict m to a subsequence of the integers in J. In Theorem 4 we construct an integer point close to a space curve satisfying certain conditions.
We write [t] for the integer part of a real number ¢, ||¢|| for its distance from the nearest integer, and (a,b) for the highest common factor of two integers a and b. Theorem 1. Let M > 12 be a positive integer, and let I be a closed interval of length M with integer endpoints. Let f(x) be a real function, twice continuously
THE INTEGER
POINTS CLOSE TO A CURVE II
489
differentiable on I, with
(1.1)
AAS wi ia sl’ @lscA 4 and
(1.13)
6
(1.14)
HOC
sos 18wo HC” M
(1.15)
2+1/L
Cy ( ) 9/2 C?
928/232T,
Then there are distinct integers mj,...,MR
(1.16)
in I with
If (mr) < 6,
and fori =1,...,n—1
there are integers k;, and powers of two qj, such that
(1.17)
OC
k;
0)
eee | Vir
K
and for’ = 2,...,n—1 (i)
(1.18)
bi
(mr) =
Kir
ih
< 36L(C
Ba
A)
Vier
’
with
KES
(1.19)
Vir S HLC3A:
Here
‘
gy Or
(1.21)
6°>M
bags Ga
dA
aT)
=a.
po ae|
L
Oe 93/232 HL O2 95/232
:
C2
bai
ide SN ee 925/232 KT,
THE INTEGER POINTS
CLOSE TO A CURVE II
491
forn > 4. Theorem 3. Let M > 12 be a positive integer, and let I be a closed interval of length M with integer endpoints. Let f(x) be a real function, twice continuously differentiable on I, with
v22 (1.22)
|
i
1 — SB A SMS 1 and A i +1
(Kn)! Deen
k+1 (3.17)
1/2
for i > 3,
cn
a
rave i(k)
i!
k+1
4
4/2*
< .2'32(CgA)!/?" Phe a!
3
< 9k 32 C(2k+2)/2" (CqA)*/2" e4
< 2k+63202(CgA)!/2 < 1/64K by (3.15), (3.9) and (3.2). From (3.16) and (3.17) we see that 1
(3.18)
1
g(Kn) — ko — 5 hak en® aS rae
Wie
Let J be the interval of values taken by g(x) + a0/K for0 2 we use 2¢ > 2i-to get
(K,N)'A; < 2*3? ( aA (ota)
)
by (3.9) and (3.39). By (3.30) the factor raised to the i-th power is less than 1/2, 80
GON dX a k
(ookehp a
z
asi nae Bom Eeey,
ees
ae
at A)V/
TL seta aia
pas
RA)
I
Hence we have
(3.42)
| me
Sa
< ok+293
SAE |32K3R gree3 (CM
k ee
6 es big
and for |n — n’| < qK» we have
(3.43)
IG(n) — G(n')| < 6.
We are now ready for the choice of n. By (3.38) and (3.40)
(3.44)
G(N')
> -——__ - —-—
+ 57
> ro.
Let n, be the smallest integer with
G(n,) > T2, Nr = bs (mod qgk2). Then n, < N by (3.38) and (3.44), and n, > 0 by (3.37). Ifn, < qKo, then
G(0) < re < G(n,) < G(0) + 6. If n, > qKo, then
G(np — qK2) < rz < G(nr) < G(np — qK2) + 4, a in both cases |G(nr) 7 r9| < 6,
M. N. HUXLEY
512
which verifies (3.33). We must also check that different integers r and r’ cannot give the same value of n. If np = np’, then r, = 71, and
Lass = r2| “< 20.
Since (3.30) gives 6 < 1/2, we see that r2 = rj, so the integer n, determines r uniquely, and our R points are distinct. For the derivatives we use ~
’ fO(m + Kin) = fO(m) + Kynf 9+) (m) +--+
k-j ey fi _— 4]
(Kyn)h
(k -—j+1)!
)
!
(k+1) (py)
ees ea q
’
for some 7 depending on n and J, with
ee
K
Cp =O;
a rational number.
:
a
(Kin)*~9
hea
Since kK, is the odd part of k!, the denominator of ¢; is at
most the power of two dividing (k — j)!, ((K — 7)!)2 in the notation of Lemma 6. We have
Pj
=;
+
Kinkjes
oe
+
(Kan)ny
le aM
(Kin)
gf?)
govt
so that for 7 >1
|S Age
lp;
gi
(Kyn)*-3+1
1
NA ge pe j
(k—-j+)!
kes
For j = 1 this is the sum estimated in (3.40) and (3.41), so
p1| < 6/K,
which verifies (3.34). For j > 2 we use (3.7), (3.9) and (3.39) with 2*>¢+1
THE INTEGER POINTS
CLOSE TO A CURVE II
513
for t > 0 to get
tone’ Dal gre aly lca k—j+1
t/2
b/2k
1
t
—jt+l1
One
x}7" for some T;, T2 = T. The resulting integral, say I(T,,T2), then takes two different forms.
The left hand side of (1.5) yields T2 (2.2)
I(T,,T>2)
=
|
Ti
I(r) dr,
FOURTH MOMENT OF RIEMANN’S ZETA-FUNCTION
521
(2.3) I(r) = 271e267 ‘i
_
2 cosh mt
KG + it)|*e~ 7% ;
i
Ay §
Mares ere ere, bars
It is easily seen, as will be shown next in §3, that this is essentially the fourth
moment of the zeta-function over the interval [T,, 7]. On the other hand, the right hand side of (1.5) leads to the alternative formula
(2.4)
Td, 15) —
T af oe maelhe p(2rixe™— 5) b(—Qmize
Ut) e27ui—w? /U? dx du dr.
Ti
In 84, we shall see that this leads to the additive divisor problem, and in §6, a
spectral theoretic expression is given for the same integral. In subsequent calculations, repeated use will be made of the familiar formula
(2.5)
‘| eAt—Be* de = Nee =
(Re B > 0).
3. An analytic interpretation of the integral /(T,,7T>) To begin with, we simplify the equation (2.3) for I(r). Clearly, the integral over t can be restricted to [0,co) with an error O(U). Moreover, the factor e™'/2 cosh rt can be simplified to 1 and the integral over u can be extended to the whole real line. Then, evaluating the latter integral by (2.5), we have
(3.1)
1,72)
= [wl NICS + it)|* 0
dt + O(TU),
where T2
w(t) = aang
| exp(26(7 — t) — (r —#)°U") dr T) T2-t
=n ?y
Tint
exp(26u — v?U”) dv.
This shows that w(t) decays rapidly as the distance of t from the interval [T,, Tz] increases, and w(t) < exp(— log’ T) if t¢ [T; — A, T. + A]. Therefore (3.1) remains valid if the integral is truncated to the last mentioned interval:
(3.2)
1(0,Te) =f
Tot+tA
w(A)IC(5 + it)|4 dt + O(TU).
522
MATTI JUTILA If we extend the v-integral to the whole real line, then the resulting upper
bound for w(t) equals exp((6/U)?) = 1+ O((TU)~?) by (2.5). Also, this gives a good approximation to w(t) if ¢ lies in the interval [7), 7] not too close to its endpoints; more precisely,
(3.3)
w(t)
=1+O((TU)~*) for t € [T,; + A, Te — Al.
The fourth moment of the zeta-function over the interval [T;, 72] may now be compared with J(T,,72) as follows. First, by (3.2), (3.3), and the wellknown upper bound < T log* T for the fourth moment, we have T2-A
I(T,,T») + O(TU) > |
w(i)le(5 +at)|*at
TM14+A T2-A
= i
1
ISS tht Of
Olle Ue lO 1
™Mm4+A
Applied with 7; — A and T> + A in place of T, and T», this gives T: ye 631 (3.4) | IS + it)|* dt < I(T, —A,T. + A) +O(TU) + O(T—'U7 log* 7).
Ti
To derive an inequality in the reverse direction, note that by (3.2) and the properties of the weight function we have Tot+A
TT 205 es if
1 ISS + it)|* dt + O(TU) + O(T~1U~? log* T).
T,-A
Applied with T; + A and T2 — A in place of T, and T>, this gives T2
1
(3.5) a SGe: it)|* dt > I(T, + A, Tz— A) + O(TU) + O(T1U~ log* T). Finally, combining (3.4) and (3.5), we obtain
(3.6)
I(T, + A,T, — A) + O(TU) + O(T-1U~? log* T)
T:Z
1
.
= ii Seas it)|* dt < I(T, — A,T) + A) + O(TU) + O(T-1U-? log? T).
FOURTH MOMENT
OF RIEMANN’S ZETA-FUNCTION
523
4. An arithmetic interpretation of the integral /(T,,7>) Coming now to the core of our argument, we analyze the integral J(T,,T>) in its shape (2.4). For this purpose, an approximate functional equation for the
function $(z) (a slight generalization of eq. (7.16.2) in [T2]) will be needed.
Lemma 1. Let z lie in the domain a < |arg z| < 1/2, |z| > b for some positive constants a and b. Then for alle > 0 we have
(4.1)
o(1/z) = — sgn(Im z)2nizo(4n7z) + O(|z|*),
where the implied constant depends only on a, b, and e.
Our goal in this section is to prove the following arithmetic formula for
our integral. This is, essentially, Lemma 3 in [H-B]. Lemma
2. Define
(4.2)
+4
F(t)=2
oe
be
S$) @?(n)n7\(t — 20)
d(n)d(n + f)f7* sin (5)
exp (—(f/2nU)?) .
n 1, we have
aX het! if |D(-ae"**)| dia x
oo ax ; oF a(m)a(n) f € (xe~“ (me? = ne~*°)) dx m,n=1
d(m)d(n)
Tite
ss
i
3
|m — n|
m,n cats(f)u - cos (Kj log(K; /4et)) exp (—(K;/2Ut)”) . Finally, summed over f, this amounts to the formula (6.5). The
Dirichlet
series approach.
The zeta-function ¢+(s) was analyzed by
Tahtadjan and Vinogradov [TV] (see also [J3] and [J4]) on the basis of its approximate representability in terms of a certain inner product involving non-
holomorphic Eisenstein and Poincaré series. Recently we sharpened (in [J4]) the estimate for the accuracy of this approximation, and in fact the representation of ¢;(s) can be made perfectly explicit.
In the Tahtadjan-Vinogradov expression of ¢¢(s) as a meromorphic function, there is a leading term with a triple pole at s = 1 giving the main term in the additive divisor problem. Likewise, this pole accounts for the main term for the integral (6.3) when the integration is shifted to the left. The next poles are encountered at the points z; and 2} with z; = $ +1«;. These are poles of the function 1/2-s
1
PT(s/2) 2. lal ty F)-HG (5) (25 /2)[7P(s — 25)0(s — 24), which represents the contribution of the discrete spectrum to ¢(s). The cor-
responding residues of the integrand in (6.3) account for the explicit terms in (6.5). We ignore here the remaining less significant ingredients in the formula for ¢f(s). The term corresponding to the pole z; is
(6.7)
5 leat ts(F (4S)
HS (S)IP(25/2)/*(C (25/2) *T(2in M5;) (z;).
By Stirling’s formula and the definition of aj, we have
losl?IC(25/2)4TRinj) _1 fay 91/8)
Pag
Hier e.
Vragh: [242ins
Further, the saddle point method gives, as above,
v(iM(te/ms 2n )t/ «5 ft/n,2V M,(zj) © —te(1/8) 5 fr
2+ing exp (—(«;/2Ut)?)
FOURTH MOMENT
OF RIEMANN’S ZETA-FUNCTION
533
Thus the expression (6.7) is approximately
T
|
re
ee
aU Ft ei M(t fy Paasts (FHF (5); ? (det /n)**9 exp NeedGry 0k2 The real part of this represents one half of the combined contribution of the poles z; and Z; to our sum over n for fixed f, and the rest of the argument is as above. 7. Remarks
on cusp form L-functions
The key property of the zeta-function in the preceding argument was the functional equation for ¢?(s), hidden in the proof of Lemma 1. Since the gammafactors in the functional equations of the cusp form L-functions are asymptotically similar to those occurring in the functional equation for ¢?(s), an extension of the above method to mean square problems for cusp form L-functions seems plausible. As an example, let us consider the L-function
Hia)ian inn m=1
related to a fixed Maass wave form. Thus the t(n) are the coefficients t;(n) for certain fixed index 7 which we drop from the notation, and likewise we write « in place of k;. Let us suppose that the form u(z) = u(x + yi) in question is
an even function of x. Then it is well known that H(s) satisfies the functional equation H(s) = x(s)H(1 — s) with (see [EHS]) 4
Maser
any
ewe! +1iK — s) T($(1 — ik — 8))
T(E(s + in) P(4(s — ix)
Note that this equals the corresponding function in the functional equation for ¢?(s) if we put formally « = 0. For fixed «, its behaviour is still similar as
| Im s| tends to infinity. Turning to the argument in [T2], §7.13 and 7.16, the role of the function ¢(z) in (1.4) will be played by the series [ee]
d(z) = Ss ine: n=1
There is now nothing to correspond to the second term in (1.4), because H(s), as an entire function, has no pole at s = 1. An analog of (1.3) then holds as such. Further, an analog of the crucial Lemma 1 also holds in a weaker form
with the error term O (|z|!/?~*(m/2 — |arg 2|)~*), which just suffices for our
MATTI JUTILA
534
purposes for we need that the exponent of |z| be less than 1/2. To verify this transformation formula along the lines of Titchmarsh, the relation T(1 — s)
x(s)
= (2n)*~?* (-i + O((lt| + 1)™*)) P(s)
is needed, and this can be seen by Stirling’s formula. In the notation of [T2], §7.16, the parameter a is taken to be 1/2 —«, and 6 stands for 7/2 — |arg z]. A standard mean value estimate for H(s) is also required. The mean square of H(s) on the critical line can now be reduced to sums related to the sum function
T(x,f)= >_ t(n)t(n+
f).
n 1. The zeta-function
2 tnjt(n + f)(n+ f)-* naturally plays the same role as ¢(s) above; for this purpose, certain recent results ( {J4]-[J5]) on this function are required. In this way, the following
analog of (1.7) and the mean value theorem of Good [G2] may be obtained: Theorem
3. For T > 2, we have
Sel
i |H(5 + it)/? d=
log)
+o)
MO),
0
where c,, C2, and the O - constant depend on the Maass wave form in question.
Acknowledgement.
The author is grateful to Prof. A. Ivié and Y. Motohashi for valuable comments and suggestions concerning the present paper. References [Al]
F. V. Atkinson,
[A2]
line, Proc. London Math. Soc. (2) 47 (1941), 174-200. F. V. Atkinson, The mean value of the Riemann zeta-function, Acta
[EHS]
Math. 81 (1949), 353-376. C. Epstein, J. L. Hafner and P. Sarnak, Zeros of L-functions Attached
[E}
to Maass Forms, Math. Z. 190 (1985), 113 -128. T. Estermann, Uber die Darstellung einer Zahl als Differenz von zwei Produkten, J. reine angew. Math. 164 (1931), 173-182.
The mean
value of the zeta-function
on the critical
FOURTH MOMENT
[G1] [G2]
[G3]
(H-B] [In]
[Iv1] [Iv2] [IM]
OF RIEMANN’S ZETA-FUNCTION
535
A. Good,
Cusp Forms and Eigenfunctions of the Laplacian, Math. Ann. 255 (1981), 523-548. A. Good, The square mean of Dirichlet series associated with cusp forms, Mathematika 29 (1982), 278-295. A. Good,.On Various Means Involving the Fourier Coefficients of Cusp Forms, Math. Z. 183 (1983), 95 -129. D. R. Heath-Brown, The fourth power moment of the Riemann zeta function, Proc. London Math. Soc. (3) 38 (1979), 385-422. A. E. Ingham, Some Asymptotic Formulae in the Theory of Numbers, J. London Math. Soc. 2 (1927), 202-208. A. Ivié, Mean Values of the Riemann Zeta-function, Tata Lect. Notes in Math. vol 82, 1992. A. Ivié, On the fourth moment of the Riemann zeta-function (to appear). A. Ivié and Y. Motohashi, On the fourth power moment of the Riemann zeta-function, J. Number Theory 51 (1995), 16—45. H. Iwaniec, Fourier coefficients of cusp forms and the Riemann zetafunction, Séminaire de Théorie des Nombres, Bordeaux 1979/1980, exposé no 18. M. Jutila, Riemann’s zeta-function and the divisor problem, Arkiv Mat.
21 (1983), 75-96. M. Jutila, Riemann’s zeta-function and the divisor problem. Mat. 31 (1993), 61-70.
II, Arkiv
M. Jutila, The Additive Divisor Problem and Exponential Sums, Advances in Number Theory, Clarendon Press, Oxford, 1993, pp. 113 —135. M. Jutila, The additive divisor problem and its analogs for cusp forms.
I, Math. Z. (to appear). M. Jutila, The additive divisor problem and its analogs for cusp forms.
II., Math. Z. (to appear). M. Jutila and Y. Motohashi, Mean value estimates for exponential sums and L-functions: a spectral theoretic approach, J. reine angew. Math. 459 (1995), 61-87. N. V. Kuznetsov, On the mean value of the Hecke series of a cusp form of weight zero (in Russian), Zap. Nauch. Sem. LOMI, AN SSSR 109
(1981), 93-130. N. V. Kuznetsov, Convolution of the Fourier coefficients of the Eisenstein-Maass series (in Russian), Zap. Nauch. Sem. LOMI, AN
[L} [M1]
SSSR 129 (1983), 43-84. N. N. Lebedev, Special functions and their applications, Dover Publications Inc., New York, 1972. Y. Motohashi, An ezplicit formula for the fourth power mean of the
MATTI JUTILA
536
[M2]
Riemann zeta-function, Acta Math. 170 (1993), 181-220. Y. Motohashi, The Binary Additive Divisor Problem, Ann. Sci. l’Ecole
[T1]
Norm. Sup. 27 (1994), 529-572. E. C. Titchmarsh, The mean-value of the zeta-function on the critical line, Proc. London Math. Soc. (2) 27 (1928), 137-150.
[T2]
[TV]
[Z]
E. C. Tichmarsh, The Theory of the Riemann Zeta-function, 2nd ed., Clarendon Press, Oxford, 1986. L. A. Tahtadjan and A. I. Vinogradov, The zeta-function of the addttive divisor problem and the spectral decomposition of the automorphic Laplacian (in Russian), Zap. Nauch. Sem. LOMI, AN SSSR 134 (1984), 84-116. N. Zavorotnyi, On the fourth moment of the Riemann zeta-function (in Russian). Preprint, Computing Center, The Far East Branch of the Academy of Sciences of USSR, Habarovsk, 1986.
Matti Jutila Department of Mathematics University of Turku SF-20500 Turku FINLAND jutilaQsara.cc.utu.fi
On the uniform of Gauss
sums
distribution
and Jacobi sums
Nicholas M. Katz and Zhiyong Zheng}
Dedicated to Heini Halberstam
Abstract. Let F be a finite field with q elements, let UV be a non-trivial additive character of F*, and y , p be the multiplicative characters of F*. We denote by G(W,x) the Gauss sums and by J(x,p) the Jacobi sums. In this paper, we consider the equidistribution properties of the following sequences in the interval [0,1] as g — oo: 1
{5pase (Uxd}
VAVo,
xFxX0;
and
1 {5 at
Su)
XP XO,
POX
=
-
We establish some equidistribution estimates with better error terms for
them. Also we give moment estimates for G(V,x) and J (x, p).
1. Introduction
and statement
of results
Let F, = F be a finite field of characteristic p, with g elements, F, be the prime field of p elements, tr and N be the trace and norm maps from F
to F,. We denote by WY the non-trivial additive character of F’ defined by W(x) = e(tr(x) /p), so that any additive character of F may be written as WV, (x) = V (az), where a € F. Thus, Vo is the trivial additive character. Let x be a multiplicative character of F* extended to F by x (0) = 0, xo be the ~ trivial multiplicative character.
The Gauss sum is defined by
G (Vax) = D> x(a) Va (a). aéF*
1Research partially supported by the National Natural Science Foundation of China
NICHOLAS M. KATZ AND ZHIYONG
538
ZHENG
The Jacobi sum is defined by
Tap) =
x(a) pl =a), acF*
where p is also a multiplicative character of F. If Va # Vo, x # x0,
P# Xo;
p#x_?, it is known that
IG (Wax) |= lJ tx p) | = Va In other words, g~!/2G (W,, x) and q~!/?J (x, p) lie on the unit circle in the complex plane.
It is of interest to consider the equidistribution properties of
the following sequences in the interval [0,1] as ¢ — ov, 1 \= ang G LT
(a,x)
} )
Va
F Vo,
XxX ca X0>
and 1 {5p eI
< Oxo),
xX # Xo;
Here, arg z stands for the argument of purpose of this paper is to establish some above sequences with good error terms. To any real numbers with 0 < 6, < éd2 < 1, and
P#X0,X
2
the complex number z. The main equidistribution estimates for the state our results, let 6; and d2 be let
Sp(51,50) = #{(Vax): Ya # Wo,x # XO (1)
1
and 6; < — argG(W,,x) < 6} 21
and
ms
IS p (51, 52) : = #4(X09) x # X00 # XOX
2
1
and 6; < 5, ate J (xP) S bo}. The main results of this paper are the following. Theorem
(3)
1.
We have
[Sr (61,2) — (51 — 62) (g — 1) (q — 2)| < 7(q—1)d(q—1)logg
and
(4)
|JS (51,52) — (61 — 52) (q — 2) (q — 3)| < 6q°/8
DISTRIBUTION
OF GAUSS SUMS AND JACOBI SUMS
539
Here d(q —1) stands for the number of positive divisors of g — 1. It is known that d(n) is O(n‘) for every € > 0, and that d(n) is not O ((logn)*) for any 6 > 0, cf. Hardy and Wright, Theorems 314 and 315. To prove the above theorem we use the Erd6s-Turan inequality in conjunc-
tion with good information on the moments of Gauss sums and Jacobi sums. For any positive integer n, we define the moments of G(W,, x) and J (x, p) as follows.
Mae
Si Ge) WaFtVo x#x0
and
X#X0 p#XO,x7!
Our original method of estimating both M,, and JM, was based on the theory of Kloosterman sheaves, cf. {Ka-GKM]. Although this theory will be used below in estimating JM,, we recently realized that there is an entirely elementary method of estimating M,. Theorem and q—1.
(5)
2. Let n > 1, Then
d:= gced(n,q —1), the greatest common
divisor ofn
|Mn| < (d-1)(q—-1)q™”.
Theorem
3. For any positive integer n, we have the estimate |JM,,| ze og
a
except in the exceptional case q even and n = 3 orn = 7, in which case we have \JM,,|
I (x%x0)” X#X0
PFO
X#X0
= JM, + (-1)” S> x((-1)") + 2(-1)" (q- 2), X#Xo
which gives
V, +2(q—2)-—1 JMn = < Vn +3(¢ — 2)
V, — 3(q — 2)
if n odd and gq odd, if n odd and q even,
if n even.
So we certainly have the inequality
(14)
|JMn| < |Vn| +3(¢ — 2).
We will prove the following estimate for |V,,|. V, estimate.
For n > 2, we have the estimate
lg"Val
T1,22,""" 5Ln
4)
(Sxteee-e)) (Tea) a
a 2)
p
i)
=(q—1)? | number of solutions in F” of NEF =l= I] (1-= 25) j
j
For any point (t1,t2,... ,tn) € F” we define f (t1,.-. , tn) = number of solutions in F” of ie ==
Ne I] (bat ae
j
j
Thus we get the following lemma. Lemma
2. We have T, = (q - Th ec (ik ee abe
The idea is to view f as a complex valued function on F”, and to compute its Fourier Transform (using the fixed non-trivial additive character V of F to define the Fourier Transform). We will eventually recover T,, by Fourier inversion.
Lemma
3. We have the formula
(PIA) (000
tn) =
oy 19°"
Proof.
70)
fn=1
To see this, it is best to work in the n-fold product ring Ff”, with
546
NICHOLAS M. KATZ AND ZHIYONG
component-wise operations.
Given x = (21, 22,.--
ZHENG
,Zn,) € F”, we define
n
2)
Norm (x) = I] z;,
Trace (x) =
j=1
y Li i
For fixed t = (ti, t2,... ,tn) € F”, f (t) is the number of solutions in F™ of the equation {e+y=t,
Norm
(a) ==
Norms (=
Le
as one sees by writing y := t—2. Let W be the non-trivial additive character of F defined by V (a) = e(tr(a@)/p), and use it to define the Fourier Transform. Then by definition, FTf is the function on F” defined by
a =(47,09,... 565) > (FETA) (ae
Se (do ajts) FO ter”
= a W (Trace (at)) f (t) tern
By the definition of f (t), we have
FTF (a)
oe
W (Trace (a(x + y)))
r,yerr Norm
=
(2)=
Norm
>
(y)=1
WV (Trace (az))
cern Norm(az)=1
CE ¥(Sen)). : £1%9°"-f,=1
For UV # Wo, a € F*, we denote by K1(n, V, a) the Kloosterman sum
Kl(n,¥,a)=
S$)
W(a, +a.+--» +a).
©1%2°''ln=a
Lemma
4.
We have
PEIN OS oO) ,
wd
ap) (PTS) Giyaeenan)
1 ,A2,°"" ,an€F™ a;#0
Ns
Sy
0| Kl(n, V,0)|? KU(n, ¥,c)] < n2qr-2)/2, S c#0
except in the exceptional case when q is even and either which case we have the estimate
Sa
Kl(n, W,c)|*
Kl(n,
V,c)
=< ee
n = 3 or n = 7, in
ont g ry)
a
c#0
Proof. For n = 1, the assertion is trivial, since the sum we are estimating is equal to —1. Thus we may assume n > 2. Pick a prime | # p := characteristic (Ff). The sum
(-1)"* S°| K1(n, ¥,c)|? K1(n, ¥, c) c#0
is the sum
of the traces of Frobenius at all rational points of G,, 7 for the
lisse sheaf Kl(n,V) @ Kl(n,V)@ Kl(n,WV). This sheaf is lisse on Gn of rank n3, pure of weight 3(n — 1), tame at zero, and all oo— breaks are < 1/n.
Suppose we know H? (Gm,r, Kl(n,V¥)@ K1(n,V) @ K1(n,WV)) vanishes in the non-exceptional case. Then the Euler Poincare formula shows that its H2}
is of dimension < n?. By Deligne this H} is mixed of weight < 3n — 2, and we get the asserted estimate. To show that H? (Gm,r, Kl(n,¥) ® Kl(n,¥)® Kl1(n,W)) vanishes in the non-exceptional case, we argue as follows. First of all, up to a Tate twist,
Kl(n,¥) ® Kl(n,W) is just the sheaf End( Kl(n,W)).
Let us denote by
Ggeom the geometric monodromy group of K1(n,W), cf. [Ka, GKM, 11.1] for the determination of Ggeom. We must show that Kl(n, ¥)@End( K1(n, W)) as a representation of Ggeom does not contain the trivial representation of Ggeom. Suppose first that either q is odd, or that n is even.
Denote by Zgeom the
center of the group Geom. It suffices to show that K1(n, V)®End( K1(n, ¥)) as a representation of Zgeom does not contain the trivial representation of Zgeom-
If n is even,
Ggeom is Sp(n),
and Zgeom is the group
+1, which
acts
by its non-trivial character on Kl(n,¥) ® End(Kl(n,W)). If n is odd and q is odd, then Ggeom is SL(n), whose center wz acts as itself on Kl(n,V) @ End( Kl(n,W)). so in both cases, Zgeom acts through a single
NICHOLAS M. KATZ AND ZHIYONG ZHENG
550
nontrivial character of itself on KI(n,¢) @ End(Kl(n, Y)), and hence we get % the asserted vanishing of H?. a Vv) (n, kl case this In odd. is 2 Suppose next that q is even, and that n > V)@ Kl(n, V)® Kl (n, U) (since W takes values in +), and so the sheaf Kl (n, kl (n, W), is just Kl (n, )°?. One knows [KA-GMK, 11.1] that Geom for Kl (n, VW) is given by Ggeom = SO(n)
Geom =
for n odd, #7
the subgroup G2 of SO (7) for
= 7
Denote by std, the standard n-dimensional representation of SO(n). To complete the proof of the vanishing of H? in the non-exceptional case, we must show that for odd n > 5, std,© has no non-zero SO(n)-invariants. Since the standard representation is self-dual, this amounts to the statement that std, does not occur in std,©”. But this is clear for n > 5, since as SO(n) representations we have
(std,)°* =
Sym? (std,) ® A’stdn.
Now A?std, is the adjoint representation Lie(SO(n)) of SO(n), and is irreducible for n > 5 because Lie(SO (n)) is simple for n > 5. As for Sym? (std,), it has the decomposition
Sym? (std,) = 1@
SphHarm?
into the direct sum of the trivial representation and the space of spherical har-
monics of degree 2, which is known to be irreducible. Thus the decomposition into irreducibles of (std,)®? is
(std,)°”
=1@ SphHarm? @ Lie ( SO(n)),
and none of these three can be std,, as already their dimensions are different. This concludes the proof in the non-exceptional cases. It remains to treat the exceptional cases q even, n = 3 or n = 7. In both these cases, we first show that the H? in question is one-dimensional. For n = 3, Ggeom is SO(3), and the decomposition into irreducibles of (std3)°? is
(stds)°? =1@
SphHarm? @ Lie( SO (3)).
Here SphHarm’ is five-dimensional, so certainly not std3, but for n = Lie(SO (3)) is the standard representation of SO(3). Thus we get
(std3)®?
=1@ SphHarm? 9 std.
3
DISTRIBUTION
OF GAUSS SUMS AND JACOBI SUMS
501
and hence (std3)®* has a one-dimensional space of SO(3)-invariants, as required. (Using autoduality of std3, one can “see” this invariant as the determinant, an interpretation we do not need here.) We now turn to the case n = 7. Here Ggeom is the subgroup G2 of SO(7). As representations of SO(7), we have a decomposition into irreducibles
(std7)®”
=1@ SphHarm? @ Lie (SO (7)),
with dimensions 1, 27, 21. Under G2, SphHarm? remains irreducible (the dimension of the irreducible representation of G2 of highest weight 2w is 27, as one computes using the Wey] dimension formula, cf. Bourbaki, Lie VIII, §9, n° 2 , page 152, where it is given explicitly for G2). But under G2, Lie (SO (7)) decomposes as Lie (SO (7)) |G2 =
Lie (G2) ® std7.
So all in all, the decomposition into irreducibles of (atd;)> 1Gs is
(std7)®? =1@ SphHarm? @ Lie (G2) @ stdz, of dimensions
1, 27, 14, 7.
Hence
(std7)°? has a one-dimensional
space of
G»-invariants, as required. Recall that we are trying to estimate, for g even and n = 3 or n = 7, the sum
(-1)"* >| Kl (n, ¥,¢) |? K1(n, ¥,c), cA#0
which, because WV is +1-valued for g even, we may rewrite as
Le
iG vcs c#0
the sum of the traces of Frobenius at all rational points of Gr for the lisse sheaf K1(n, wy)? . We have just proven that for n = 3 or n = 7, this sheaf, on G,,7, contains one copy of the constant sheaf. Therefore, at least one of its oo—slopes must vanish. But as all oo—slopes of Kl(n,WY) are 1/n, all oo—slopes of Kl(n, yw)? are 0, and if g(n) < G(n), then (3.8)
V (G(1)}
yee)
Vp—a(klBn + 4),
ESTIMATION
OF EXPONENTIAL
SUMS
579
for some real y, and
(3.10)
ENF)
aig ss
Vip)
hi
= Dy.
To prove Proposition A, we also need the following two lemmas.
Lemma 3.1. Let g(n) be a real arithmetic function, f(n) a polynomial with real coefficients, and
S=
J> g(nje(f(n)). a > (P(BR))™® =(y = m1 Bi + +++ + re Be ET). Observe that the subspaces V° and V+ of V, generated by the subsets [° = {y €T : ¥(y) = 0} and I+ = {y ET: ¥(y) F 9}, satisfy V° © v= Hence the preceding construction of B splits up in two parts, that of a basis B* = {f;,...,(%} of V+, and that of a basis B° = {6:41,..., 84} of V°, say. We set
p(B) =0
for
BEB,
and are left with the system of equations
b(y) = (p(A1))™ + (PCB)
(Y= 1B ++
+ me EP).
Writing ¥(y) = e”™ and (8) = e?) with w(y7), z(B) mod 27i, we obtain the system of linear equations wy) = 12z(B1) +--+ 42z(F:)
mod
2mt
(y=mfi+---+ ne
€ ad)
for z(3;),..., 2(). It reduces to a system of ¢ linear equations having rank t, since w is multiplicative on P+ C A and dim I+ = ¢. Therefore its determinant is a nonzero integer +D with D € N, and the numbers z(/),..., z(G) are uniquely determined mod a which shows the existence of a nontrivial multiplicative homomorphism y : M — C coinciding with 7 on I. Observe that, in particular, the vector space V over Q generated by I contains M and, by construction, has minimal dimension. Hence, in this situation, the boundedness of w implies that of y. We now turn to the case r > 1. Consider the projections [),...,T,. R, of [CR,” in the directions €1,--.,€,, representing the vectors of the standard basis of the real vector space R". By applying the one-dimensional version of Lemma 1 to each of the finite sets [y,...,I, with respect to the corresponding projections
A;,...,A,
of A, the existence of the sets Bigs:
Dey
WEIGHTED
WIENER-LEVY THEOREMS
615
having the desired properties follows. This construction of B,...,B, gives vector spaces V; D [j,...,V, D> I, of minimal dimension over Q, and M = {B,e, + -:- + Be, | Bi € Bi,...,8, € B,}. Hence the existence of a
nontrivial (bounded) homomorphism y : M — C such that y = # onT
follows
as in the one-dimensional case. Returning to the proof of the Density Lemma we notice that Lemma 1 associates the finite set [ C A occurring in (12) with a finite set T Cc N¢. Namely, let By = {Go1,---, Pox, } where kp € No for g=1,...,r in Lemma 1, and set k = kj +---+k,. We may assume k € N. Then T is defined by
(jay keys
oe
sty eee pie
if and only if
A = (n11 811 +++
+ 1b, Pik) €1 + ++
+ (Mri Ber +++ + Ark, Brk,) er ET.
Furthermore, Lemma 1 carries over the multiplicativity and the boundedness by 1 from w to y. This gives
P(A) = (p(Gr1e1))"* ++ (P(Bre,er))"** and the sums occurring in (12) take the form
Yo eQ)¥OA) = Q(~(Bire1), «++ -P(Brkxer)) € QD") der with a polynomial Q in k complex variables, and similarly
So a(a)en>* = Qe, ... ePrtrPr)€ Q(n(H")), AET
where 77 : H’ — D’ is defined by
(15)
z=n(s) =(eP"",... Bp
a ae ee
hc)a)
fois = (Spec cseen) Density Lemma.
Hi’. Finally, the next lemma completes the proof of the
Lemma
that f : ioe — C is a continuous function, holomorphic
on D*.
2. Assume
Then, with the mapping 7 : ees De from (15), the set f(n(H’)) is
dense in f(D").
Proof. We adapt the method of Schwarz and Spilker [15], where the case r = 1 is treated as Hilfssatz 5.1. Let vu € f(D") and g(z) = f(z) —v for z€ D*. We
616
LUTZ LUCHT AND KLAUS REIFENRATH
have to show that
(16)
inf{|9(z)| | z € n(H”)} =0.
Suppose, on the contrary, that with some ¥ > 0
(17)
lg(z)| > 0
For fixed o = (o1,...,0,)
forall z €n(H’).
€ Ry we set
Loe ={zeE Cra Zon| = enPen?e (1S Kee | RSS Since By, =
Se NP
{Box | 1 < & < ko} C Ry is linearly independent
over Q for
every 0 =1,...,7, the set n({o + it | t € R"}) is dense in L, by Kronecker’s approximation theorem (see, for example, Hardy and Wright [4], Theorem 444). Therefore (17) even holds for all z € L, with ao € R,”. Since 0 € D* is limit point of n(H'’) we obtain also |9(0\ | from. (17). For fixed ¢ = (o1,...,0,) € Ry we set further K, ={zeC*
| IZon| S ear tea (Tee
ko l 0 by
— 0 a =inf{é € Ry |\g(z)| 25 for allz € Ke}. Since g is a zerofree continuous function of K,, and holomorphic on Kg, for every 3 > a, the maximum principle yields
max {|7
eS Ko} = max {||
2 € Ins}
8
for all z € Ka.
Assume that a > 0. Then |g(z)| < J for some z € Kg, by definition of a. Hence a = 0 and
lg(z)|>9
forallzeD*,
WEIGHTED
WIENER-LEVY
THEOREMS
which contradicts v € f(D*) and proves (16).
617
This completes the proof of
Lemma2.
4. Inversion
theorems
and Euler products
The case F(z) = z~*, Q = C% of Theorem 2 is of specific interest. Evidently (4) is then equivalent to the Wiener type inversion condition
(18)
la(s)| > 6 >0 for alls € H”.
An important class of functions a € £1,(M) is that of multiplicative functions in which case @(s) has an Euler product representation. In order to explain these notations we need some arithmetical preparation. It is well known that the Euler product representation of an ordinary Dirichlet series having multiplicative coefficients is the analytic analogue of the Unique Factorization Theorem in N. In this section, we consider free multiplicative semigroups M of real numbers n > 1 with 1 € M, by which we mean that there exists a countable subset P C M of free generators, the “prime elements”, such that every n € M, n # 1, has a unique decomposition into finitely many elements of P, apart from their order. Observe that, in contrast to the notion of a multiplicative arithmetical semigroup in the sense of
Knopfmacher [8], M may have finite limit points. If M),..., M, are free multiplicative semigroups generated by P;,...,P,, then M, x --- x M, is generated
by
UGbataes
oo spo con a
1l 0. Hence, with
=> 1 |[%>9, pEG
(18) results.
References
[1] Edwards, D. A., On absolutely convergént Dirichlet series, Proc. Math. Soc. 8 (1957), 1067-1074. [2] Edwards, R. E., Fourier series, Vol. I and II, New York 1967.
Amer.
WEIGHTED
WIENER-LEVY
THEOREMS
619
Gelfand, I. M., Uber absolut konvergente trigonometrische Rethen und In-
tegrale, Rec. Math. (Mat. Sbornik) N.S. 9 (1941), 51-66. Hardy, G. H., Wright, E. M., An introduction 3rd ed., Oxford 1954.
to the theory of numbers,
Heppner, E., Schwarz, W., Benachbarte multiplikative Funktionen, in: Studies in Pure Mathematics (To the Memory of Paul Turdn), Akadémiai Kiad6-Birkhauser 1983, 323-336.
[7]
Hewitt, E., Williamson, J. H., Note on series, Proc. Amer. Math. Soc. 8 (1957), Ingham, A. E., On absolutely convergent Math. Analysis and Related Topics. Essays 1962, 156-164.
absolutely convergent Dirichlet 863-868. Dirichlet series, in: Studies in in Honor of G. Pélya, Stanford
[8] [9]
Knopfmacher, J., Abstract analytic number theory, Amsterdam 1990. Lévy, P., Sur la convergence absolue des séries de Fourier, C. R. Acad.
[10]
Sci. Paris 196 (1933), 463-464; Compositio Math. 1 (1934), 1-14. Lucht, L., An application of Banach algebra techniques to multiplicative
functions, Math. Z. 214 (1993), 287-295.
[11] [12] [13] [14] [15]
[16] [17]
Lucht, L., Weighted relationship theorems and Ramanwan expansions, Acta Arith. 70 (1995), 25-42. Newman, D. J., A simple proof of Wiener’s 1/f theorem, Proc. Amer. Math. Soc. 48 (1975), 264-265. Reifenrath, K., Gewichtete Wiener—Lévy-Satze und arithmetische Halbgruppen, Dissertation, TU Clausthal 1995. Rudin, W., Functional analysis, New York 1974. Schwarz, W. Spilker, J.. Wiener-Lévy-Satze fur absolut konvergente Reihen, Archiv Math. 32 (1979), 267-275. Wiener, N., Tauberian theorems, Annals of Math. 33 (1932), 1-100. Wiener, N., The Fourier integral and certain of its applications, Cambridge
1933.
Lutz Lucht and Klaus Reifenrath Institut fiir Mathematik
Technische Universitat Clausthal Erzstrage 1 - 38678 Clausthal—Zellerfeld
GERMANY
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rooney
1 LOE: RTs
;
vedio’
_ 7
ia
ae ser 0 for each 7, and it has the Fourier expansion y ==—J) T'(s;)
(2a |nly)e(nz). U5 (nr) ( ) Ki, t; ( | ly) ( )
The Fourier coefficients v;(n) are proportional to the eigenvalues A;(n) of T;, :
vj(n) = 9; (1)Aj(n),
form > 1.
The eigenvalues A;(n) enjoy the following multiplicative property:
mn AyOm)As(n) = > Ay (A) d|(m,n)
The automorphic function associated to u;(z) is given by the absolutely convergent series co
Bia
pyar n=)
for Rs > 1, which has analytic continuation to an entire function and satisfies one of the functional equations 6;(8)H;(s)=6;(1
— s)HF(1
—s),
if 6; =
O;(s + INH; (s) = —0,(2 — s)7i,(1— 3),
in
“if 0; = =,
where
Our main result is
Theorem
1. We have
(1)
a
[H;(s;)|*
Pee
eke
T1.
The implied constant depends only upon e.
We have H;(sj)
« t87*.
Theorem 1 will be deduced from the following general inequality:
SPECTRAL Theorem
(3)
MEAN-VALUES 2.
OF AUTOMORPHIC L-FUNCTIONS
623
We have
DS
LDS andy(nm)? < (N+ T)(NT)*
T 1, (13) E(z,s) Es y? os jae
=
5)¢(2s ed 1)
13
D'(s)¢(2s) Meno + Oaey
pits ?01~-26(|n|)K,_1(2n|n|y) exp(27inz) .
Here ¢(s) is the Riemann zeta-function, o,(n) the sum of the ath powers of the divisors of n, and K,(x) the K-Bessel function of order v (cf. [3, p.140]). Thus E(z,s) is a meromorphic function over the entire s-plane.
ON KUZNETSOV’S
TRACE FORMULAE
643
We then consider the Petersson inner product of P(z,s1) and P,(z, 52) with m,n > 1 and Re(s;) = 0; > $j == is
(Pts
$2), Pn (-5 88) =
| Pale
s)Pae
abdul),
where ¥ is the usual fundamental region of [, and du(z) Poincaré metric. The estimate (1.4) implies that the integral lutely and represents a regular function of s; and s» in the As a particular instance of the unfolding argument of Rankin see that the expansion (1.2) gives, for 01,02 > 1,
= y~?dxdy the converges absoindicated range. and Selberg we
1)(4mm)1~81—82 (Pm(+, $1), Pr(-,52)) = Omnl (81+ $2 —
As
a yer =
tSTM
S82—8,—-1l1
=
17251 5
S(m,n50)
-] 5
; ap~ eae Danae
where dm,7 is the Kronecker symbol.
21 esa
dێ ee om ea
To ensure the absolute convergence
on
the right side we impose the condition (1.7)
CoO
la
In it we may exchange freely the order of sums and integrals in (1.6) and have (Pec
Si) piki e,8 2) Tai cme
(1.8)
Gh a 89)
D(Amm)\n
ae Se [7251 S(m,n;l) if (1 ais ca mee Sear (€ ;m,n,l)d€,
1=1
Ee
where oo 2 Y,,(€;m,n, 1) = ik aes exp (— 2nny(1 + 2€) — mae)
So far we have followed the Selberg-Kuznetsov argument. But we now depart from it. We are going to transform the integral in (1.8) into an expression similar to Barnes’ integral representation of the hypergeometric function. To this end we note first that Mellin’s formula gives Yoke pind!)
2am = hyLisl fa bet expl—2any(t +18) (esl once
7
dindy,
YOICHI MOTOHASHI
644
where (a) is the vertical line Re(7) = a > 0, and |Arg(1 — i€)| < $m. This double integral converges absolutely if Re(w) +a > 0. On it we exchange the order of integration and compute the inner integral, getting
: 2 =2n (1s YolEimimt) = seeeany fFroNRn ew)(7) eee, where |Arg(1 + 7£)| < $7. So, providing Cia
a+o2-—0,>0,
we have [are
i hh lane ratae m, 7 ay ae
py any.
I
Oe
erst
(1 + 2€)0+82
This double integral converges absolutely if
(1.10)
a-o,+5 3 and
O(s1,52;7T) =T(s1 - 5 +ir)T(s, — 5 —ir)T(s2 - 5 + ir)T(s2 — 5 — ir). It should be remarked here that as is shown uniformly for any integer m > 1,
(1.19)
>
in the next section
we have,
|as(m)Pe-**!
Iaj(m)Pe™ 2
—TK;
K/2 1. This suggests apparently the relation lo)
(3.6)
w(t
ei =sinh(nt)
We are going to prove it rigorously.
oo cosh(mr)
g(t, 7) Join (x) dr.
ON KUZNETSOV’S
TRACE FORMULAE
653
To this end we consider the expression
*(t,n) =< a sinh(at
37 (
)
-
( 7)
t >
a
[(n — 3 +ir) ae rBEA aa oe EY )i
éosh(nr)
Z r(3 Sits
p]
ir)
where |Im(t)| < a+ 4 < a (cf. (2.4)). We shift the contour to the line Im(r) = —K with an arbitrary integer K > 1. We can sum the residues thus resulting by the formula (3.3), and find that
ons
sin(77) n
T(n + it) 0(n — it) + wk (t, 7)
Mg i 2t cosh(mt)
(kK +it) T(K+7+ it) n T(K+1-7n+ it)
_ (Kit) TK +n-2t) "hd 00, Geer etn where w3(t,7) is the contribution of the integral with the new contour.
By
Stirling’s formula we see that the expression in the braces is O(K?%~') and also
widen) < f+ he co
*
K
—2n|r|
T(K+n-$+i (K+7-35 ir) |r
=00:
3 and @ is as in (1.18).
Then we specialize (5.2) and (5.4) by (2.1), getting
co
—on on wa
j=l
egypt + airy (mn) |C(1l 5 ; Ne Se
BOBS)
ha
= = wh 7S(on, —n;l)w_ (t,=
29
er
)
(ul
where g(t,7r) is as in (2.2), and
i
w_(t,2) = —
271
/ D(n + 2t)0(n - it)(=)
(a)
z
1-2
Gp
with t, @ satisfying (2.4). As before we let f satisfy C, multiply both sides of (5.5) by cosh(mt) f(t + $i), and integrate with respect to ¢ over the real axis; here the absolute convergence is easy to check. Then we are left with the evaluation of
iesw_(t, x) cosh(mt) f(t+ 5i)dt. —oco
It is equal to
(5.6)
=
(=)
1-—2n
oe
/
P(n + it)P(n — it) cosh(at) f(t + 5i)dtdn.
ON KUZNETSOV’S
TRACE FORMULAE
663
In the inner integral we shift the contour to Im(t) = —3, and it becomes
-if- D(n + it+ $)0(n - it — 5) sinh(xt) f (t)dt
= =f
{ries $)I(n — it — 3)
—T(n —it + $)P(n + it - »|sinh(mt) f(t)dt = / i(n + it — $)0(n — it — $) sinh(xt) f(t)dt. We insert this into (5.6), exchange the order of integration, and compute the inner integral by (5.3). We thus obtain the following version of the Kuznetsov-Bruggemann trace formula: Theorem
3. /f f satisfies C, then we have, for any integers m,n > 1,
Bee H+ ef Gane ayes BS simone
=
(mY
where
vay = 4 [_rsint(ar) Kail) f(r)
(5.7)
Now we turn to (5.1) and assume that ¢ satisfies the above condition D. Unfortunately we do not have an analogue of (4.2), which would make our problem easier. We can, however, come close to it. This is by virtue of the fact that
(5.8)
W_(z38,8+5) =V7e*,
which is equivalent to the identity K1 Ce
(1/2x)2e7*.
The specialization
of (5.2) and (5.4) that is indicated by (5.8) gives, for Re(s) > 3, 1
(5.9)
(21/mn)*s—* Se pas 3(™ —n;l) exp (= l=1 —
pj (™m)pj(—)
2 ~cosh(mes) . 7s
1
[° —
a
i
orir(m)orir(n) s,r)dr "4? _ ie (mn)'"|¢(1 + Dir) ane
664
YOICHI MOTOHASHI
A(s
1 O(s,s+4; rs perSneieey Ar eh
T(2s — 3)
2/0
= 23-48\/m cosh(1r)
— 12s — ir Ie [T'(2s —1+4+ 2ir)P(
oa =
(
We note, in advance, that we have
Nar) = 2eosh(ar) f Beek
(5.10)
(cf. (1.15) and (1.16)). We are going to extract the sum (5.1) from (5.9) by integrating the latter. But the presence of the exponential function on the left of (5.9) causes a minor trouble. To overcome it we introduce a C™ function wx depending on a positive parameter X such that Dy wx
for aA,
(x) =
OSStoreg 2a22Xe: and for each fixed v > 0
(5.11)
a)(2) 4m\/mn which we suppose hereafter. We follow closely the argument that we used to prove (4.9). Then we see that the formula (5.9) gives
(5.12) K_(m,n;y) =
$ palem)pj(~n)
A)
ay
es —oo(mn)" |¢(1 + 2ir)|? Ax (r)dr,
=|
ON KUZNETSOV’S
TRACE FORMULAE
665
where
Ax(r).= 1 2
271
A(s,r)0%(s)ds (a)
with a as in (4.8). But (5.10) gives obviously
Ax(r) = 2eosh(ar) |0 oR cx (x) ple)Kain2) dz=. So we have, by (5.3),
eo (r) —Ax(r) = deosh(ar) f° (1— ex c))ola) Kaie(a)= Za cosh id T(s= (ee #ho ir)(s Fea 1
= —cosh(mr
—$—ir
*(s)ds, (1 l-w — wx)p)*(s)
where y~ is defined by (5.13), @ > } and
(A= @x)9)*(s) = /“(d= wx(2))e(@)(2) ae. The condition D and (5.11) imply that ((1 - wx))*(s) is regular for Re(s) >
— 6 and there
(1 — wx)y)*(s) « X~29(|s|
+1).
Thus we have 1 yp Saree (r) — Ax(r) 4 ae ee cosh(ar)
f
ae) s
+ cxh(nrf (1 — wx)y)*(F + ir)P(2ir)
+(l—axy)eG— wpr-ain which is O(X~79(1 + |r|)~2~2°). We insert this into (5.12) and let X tend to _
infinity. In this way we are led to
YOICHI MOTOHASHI
666 Theorem
4.
[f ¢ satisfies the above condition D, then we have, for any
integers m,n = 1,
5(m,—n;)o(2¥™)
ioe||)— ~
1
2
1
[°°
oair(m)orir(n)
p;(™m)p;(—n) *~ (K;) a ae in (mn)"|¢(1 = ~cosh(mK;) = ye
n
a 2ir)|? Yp
(r)dr,
where
(5.13)
a(t) = 2cosh(nr) | (2) K2ir(2) —.
Acknowledgement. We are indebted to Professors H. Iwaniec and M. Jutila for their valuable comments which they made on the draft of the present paper. We note that after finishing this work we learnt that Professor Iwaniec recently published his lecture notes “/ntroduction to the Spectral Theory of Automorphic Forms” ( Revista Matematica Iberoamericana, Madrid 1995 ). In this elegant book a unified treatment of the spectral resolution of the hyperbolic Laplacian as well as the subject related to ours can be found.
Addendum (Feb. 26, 1996): In the meantime we have obtained a further simplification in the proof of Theorem 1. Thus the identity (3.2) can be dispensed with, and we can proceed directly from (2.2) to (3.10). Also we have found that the above argument can be refined to yield a unified account of the trace formulas and the Fourier expansion of the resolvent kernel of a Fuchsian group, which is based on the theory of real analytic
Poincaré series, and which is quite different from the Niebur-Fay analysis. It may be worth remarking that in our new argument for the resolvent the following integral formulas of the Barnes type play important réles:
=f gsin(ne)r(s: +60 (s2 + OT (65 +6) (T)
“D(a = €) (sa =
SE sate dé
T(s; + 5)D(s2 = $)0(s83 ar 5) P(s1 sr 82)T(s1 AF $3):
-T(s2 + 83)/T'(s1 + 82 +8345),
ser | §sin(2ne)P(s1 + (2 + OE (s9 +6) -T(s1 — €)0' (82— €)0'(83 — €)d€ = [(s1 + s2)I'(s1 + 53)T'(s2 + 53).
ON KUZNETSOV’S
TRACE FORMULAE
667
Here the paths separate the poles of ['(s; + €)I'(s2 + €)I'(s3 + €) and those of I(s; — €)P'(s2 — €)I(s3 — €) to the left and the right, respectively; and the parameters $1, 52,53 are assumed to be such that the paths can be drawn. The
proof of these formulas is not difficult. Using (+) we may transform (1.11) to an identity that is equivalent to the result of applying Theorem 1 to the right side of (1.18). In the same way the formula (t) yields the transformation of (5.2) that is equivalent to the result of applying Theorem 3 to the right side of (5.4). The point is that we are able to do these transformations without appealing to the spectral resolution of the hyperbolic Laplacian. The new Fourier expansion of the Poincaré series thus obtained is essentially equivalent to the Fourier expansion of the resolvent kernel for the hyperbolic Laplacian over the full modular group. Naturally the argument extends to any co-finite groups. The details will be published elsewhere.
References
[1] R.W. Bruggemann, Fourier coefficients of cusp forms, Invent. math., 5(1978), 1-18. [2} N. V. Kuznetsov, Petersson’s conjecture for forms of zero weight, and Linnik’s
conjecture,
Preprint,
Habarovsk Complex Res. Inst., East (Russian); see also Math. USSR
Siberian Branch Acad. Sci. USSR, 1977.
Sbornik, 39(1981), 299-342.
[3] N. N. Lebedev,
Special Functions & their Applications,
Dover Publi-
cations, New York, 1972.
[4]
Y. Motohashi, On the Kloosterman-sum Acad., Ser.A 71(1995), 69-71.
zeta-function,
Proc. Japan
[5] A. Selberg, On the estimation of Fourier coefficients of modular forms, Proc. Symp. Pure Math., 8(1965), 1-15.
Yoichi Motohashi Department of Mathematics College of Science and Technology Nihon University Surugadai Tokyo-101 JAPAN [email protected]
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