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60
УДК 519.14
ON THE PERIODIC ZETA-FUNCTION
M. Stoncelis, D. SiauCiunas (Siauliai, Lithuania)
Abstract
We present an universality theorem for the periodic zeta-function which is defined by a Dirichlet series with periodic coefficients satisfying a certain dependence condition. This simplifies the problem and allows to elucidate the universality of the periodic zeta-function.
Keywords: analytic function, Dirichlet series, periodic zeta-function, universality.
О ПЕРИОДИЧЕСКОЙ ДЗЕТА-ФУНКЦИИ
М. Стонцелис, Д. Шяучюнас (г. Шяуляй, Литва)
Аннотация
В статье доказана теорема универсальности для периодической дзета функции, которая опредеяется рядом Дирихле с периодическими коэффициентами, удовлетворяющими некоторому условию зависимости. Это упрощает задачу и разрешает осветить универсапьность периодической дзета функции.
Ключевые слова: аналитическая функция, периодическая дзета функция, ряд Дирихле, универсальность.
1. Introduction
Let s = a + it be a complex variable, and a = {am : m E N} be a periodic sequence of complex numbers with minimal period q E N. The periodic zeta-function Z(s; a) is defined, for a > 1, by the series
c(s; a) = £ ^
m=l
In view of the periodicity of the sequence a, we have that, for a > 1,
1 q
c (s; a) = q-sHaiC (s 0'
where C(s; a) is the classical Hurwitz zeta-function with parameter a, 0 < a ^ 1, which is defined, for a > 1, by the series
<x
c (s,a) = Y1
n(m + a)-'
m=0 v '
and is continued analytically to the whole complex plane, except for a simple pole at the point s = 1 with residue 1. Therefore, equality (1) gives a meromorphic
continuation for C(s; a) to the whole complex plane. If
q
def 1 V^ n a = - } ai = 0,
H i=i
then the function C(s; a) is entire one. Otherwise, C(s; a) has a simple pole at the point s = 1 with residue a.
Let x be a Dirichlet character modulo q, and L(s,x) denote the corresponding Dirichlet L-function. It is well known, that for (b,q) = 1,
cq) = 4 £ xm(s.x).
X=x(modq)
where summing runs over all p(q) Dirichlet characters modulo q, and p(q) is the Euler function. Therefore, denoting by (l,q) the greatest common divisor of the numbers l and q, we find from (1) that
1 JL / «
z (s; a) = - / , ^jZHL
¿ at((s, 4A
ti V J
i aM £ *((fe) l(s,x)
1 v- < t^D )
X_x(mod jf^ )
= £ k^W £ 4 и)L(sX (2)
X=x(mod (q )
In [9] J. Steuding, assuming that q > 2, am is not a multiple of Dirichlet character modulo q, and that am = 0 for (m, q) > 1, obtained the universality of the function Z(s; a). Let D = {s E C : 2 < a < 1}, K be the class of compact subsets of the strip D with connected complements, and H(K) and H0(K), K E K, be the classes of continuous functions on K and of continuous non-vanishing functions on K, respectively, which are analytic in the interior of K. Then J. Steuding proved the following statement, Theorem 11.8 of [9].
Теорема 1. Suppose that q and a are as above. Let K E K and f (s) E H(K). Then, for every £ > 0,
liminf ^meas < т E [0,T] : sup\((s + ir; a) - f (s)| < e \ > 0.
т^ж T [ seK J
Here and in the sequel, measA denotes the Lebesgue measure of a measurable set A с R.
If am = c, m E N, with c E C \ {0}, then the sequence a is periodic with q =1. In this case, we have that
Z(s; a) = cZ(s). (3)
If am is a multiple of a Dirichlet character x modulo q, i.e., am = cx(m), m E N, with a certain constant c E C \ {0}, then, clearly,
Z(s; a) = cL(s,x). (4)
Since the functions Z(s) and L(s,x) are universal in the Voronin sense [1, 5, 9, 11], we have that, in the cases (3) and (4), the function Z(s; a) is also universal.
Теорема 2. Suppose that am = c = 0 or am is a multiple of Dirichlet character modulo q. Let K E K and f (s) e H0(K). Then, for every £ > 0,
liminf ^meas < т E [0,T] : sup\((s + ir; a) - f (s)\ < e \ > 0. T [ seK J
We observe that the approximated function f (s) in Theorem 2 is different from that in Theorem 1: in Theorem 1, f (s) is not necessarily non-vanishing.
The aim of this note is to consider an example of the function ((s; a) with prime q, where
1 9-1
= ^qy Eai- (5)
This example elucidates the situation.
We say that ((s; a) is universal if the inequality of universality
liminf -meaJ т e [0,T] : sup\((s + ir; a) - f (s)\ < el > 0 т^ж T { s&K J
with every e > 0 is satisfied for all K e K and f (s) e H0(K). If this inequality is satisfied for all K e K and f (s) e H(K), we say that ((s; a) is strongly universal. Let, for brevity,
q-1
b(q,x) = ^2 ai x(l), x = x(modq)-
1=1
We suppose that am ^ 0, m e N. Then the following statement is true.
Теорема 3. Suppose that q is a prime number, and that the periodic sequence a = {am : m e N} with minimal period q satisfies equality (5). 1° If the sequence a satisfies at least one of hypotheses
i) am = c, m e N;
ii) am is a multiple of a Dirichlet character modulo q;
iii) q = 2;
iv) only one number b(q,x) = 0, then the function ((s; a) is universal.
2° If at least two numbers b(q, x) = 0, then the function ((s; a) is strongly universal.
The proof of assertion 2° of Theorem 3 is based on the Voronin theorem on joint universality of Dirichlet L-functions.
2. Voronin theorem
We remind that two Dirichlet characters are equivalent if they are generated by the same primitive characters.
Теорема 4. Suppose that xi,---,Xr are pairwise non-equivalent Dirichlet characters and L(s,x1), ■ ■ ■, L(s,xr) are the corresponding Dirichlet L-functions. For j = 1,... ,r, let Kj e K, and fj (s) e H (Kj). Then, for every e > 0,
1
< r e [0,T] : sup sup \L(s + ir; xj) - fj(s)\ < e \
I Kj^r seKj I
liminf —mea^ t £ [0,T] : sup sup \L(s + ir; Xj) _ fj(s)| < W > 0.
Theorem 4, for circles in place of the sets Kj, was obtained by S.M. Voronin and applied for the functional independence of Dirichlet L-functions in [10]. A full proof of this case is given in [4]. The Voronin theorem in the form of Theorem 4 can be found in [9] and [6]. Modifications of Theorem 3 also were obtained by S.M. Gonek [3] and B. Bagchi [1, 2].
A very good survey on universality of zeta and L-functions is given in [7].
3. Mergelyan theorem
Approximation theory of analytic functions is one of the most important fields of mathematics, and has a long and rich history. In universality of zeta-functions, a very useful is the Mergelyan theorem on the approximation of analytic functions by polynomials. This theorem is a generalization of results of many authors, and is a final point in the field.
We state the Mergelyan theorem in a convenient for us form.
Teopema 5. Suppose that K C C is a compact subset with connected complement, and that F(s) is a function continuous on K and analytic in the interior of K. Then, for every £ > 0, there exists a polynomial p(s) such that
sup \f(s) — p(s)| < £.
s&K
Proof of Theorem 5 is given in [8], see also [12].
4. Proof of Theorem 3
The cases i) and ii) of assertion 1° are contained in Theorem 2. Since q is prime, we have that (l,q) = 1 for l = 1,... ,q — 1, and (l, q) = q for l = q. Therefore, we deduce from (2) that
1 —
Z (s; a) = qs E x(1)L(s,x) + a E x(l)L(s,x)
X=x(mod1) 1=1 x=x(modq)
1 q-i
= Of Z (s) + ai E x(l)L(s,x). (6)
l=1 x=x(modq)
It is well known that if xo is the principal character modulo q, and p denotes a prime number, then
L(s,Xo) = Z(s)n(1 — f) = Z(s) (1 —
p\q
in our case. This and (6) show that
1 ( 1 — ^ z(s) —
Z(s; a) = * ^ — -q) E ai) Z(s) + -q) E ai
1 q- 1 _
+ -qyEai E x(l)L(s,x)
l= 1 X=x(modq)
Z ( ) q-1 1 q-1
= —| ^01 + W) ^a' ^ X(DL(s,x) (7)
1=1 1=1 x=x(modq)
X=X0
in view of (5). In the set {x : X = x(m°dq)}, replace the principal character modulo q by the character x(m°d1), and preserve the notation x = x(modq). Then (7) we can rewrite in the form
l q-1 l
Z (s; a) = piqj^ a ^ X(l)L(s,X) = —q) Y1 L(s,X)b(q,X)- (8)
l=1 X=x(modq) x=x(modq)
Now we consider the case iii) of 1°, i.e., q = 2. By (8), we find that, in this case,
Z(s; a) = Z(s)b(2,x) = aiZ(s).
Thus we obtain the case i).
We note that at least one number b(q,x) in (8) is non-zero. Suppose that only one of the numbers b(q,x) is non-zero. Let b(q,x) = 0. Then, by (8),
1 1 q-1 Z (s; a) = —q)Z (sS)b(q^ = —q)Z (s) £ 01-
Thus,
l q- 1
a1 = • • • = aq-1 =
—(q) 1=1
y^ai = Oq,
and we have again the case i).
Now let b(q, x) = 0 for some x = x(modq). Then (8) gives
1 q-1
Z(s;
a) = —q) L(s,x) £ ai x(l)
Hence,
q— 1
ai = X(l)Y] aiX(l) —(q) t!
for all l e N, and
_ _ 1 q—1 _
a1X(1) = • • • = aq—1X(q - 1) = Yl aix(l)-
Thus, al = a1 x(l), l £ N, and we have the case ii).
It remains to prove 2°. Denote by H(D) the space of analytic functions on the strip D equipped with the topology of uniform convergence on compacta. Preserving
the above notation, i.e., in place of x0(modq) using x(mod1), we define the operator F : Hv(q)(D) — H(D) by the formula
F (g x(s) : x(modq)) — ^q) gx(s)b(Q,x),
X=x(modq)
(gx(s) : x(modq)) E H^(q)(D).
First we will prove that, for every K e K and polynomial p = p(s), there exists (gx(s) : x(modq)) e F-1{p} such that gx(s) = 0 on K for all x(modq). Suppose that
b(q,Xj) = 0, j = 1, 2.
Since the set K is bounded, there exists a constant C E C such that
p(s) + C = 0 on K,
and
C
v(q)
Y b(q,x) = o.
X=x(modq) X=X1X2
We take
gxi (s) = 'Aq)b-i(q,xi)(p(s) + C),
(
gx2 (s) = Ф)ь (q,X2)
C
q)
Y1 b(q,x)
V
x=x(modq)
x=xi ,x2
/
and gx(s) — 1 for x — Xi, Then we have that gx(s) — 0 on K for all x — x(modq), and
F (gx(s): x — x(modq)) — p(s)■
Let, for brevity,
q-i
M — Y, \ai\,
i=i
and let t e R satisfy the inequality
sup sup\L(s + ir,x) - gx(s)\ < 2M'
X=x(m°dq) s£K 2M
where gx(s) has the above properties. Then, for such t, by (8) suP K(s + iT; a) - P(s)\
s&K
1
1
sup \F (L(s + ir,x) : X = X(modq)) — F (9x(s) : x = x(modq))\
seK
M
^ sup s&K -(q)
E \L(s + iT,x) — g%(s)\
X=x(modq)
£
^ sup sup\L(s + iT,x) — gx(s)\ < 2•
X=x(modq) s£K 2
:iq)
Since q is prime, the characters x = x(modq), where x0 is replaced by x, are pairwise non-equivalent. Therefore, by Theorem 1, the set of t E R satisfying (9) has a positive lower density. However, (9) implies (10). Thus
{
liminf — meas { t E [0, T] : sup \Z(s + iT; a) — p(s)\ < - 1 > 0 t^^ T | S^K 2 J
s&K
2
11)
for every polynomial p(s).
It remains to replace the polynomial p(s) by f (s). By the Mergelyan theorem (Theorem 5), we can find a polynomial p(s) such that
If t e R satisfies
then, in view of (12),
This shows that
!
sup \f(s) — p(s)\ < s&K 2
sup\Z(s + iT, a) — p(s)\ < ^ s&K 2
sup \Z(s + -it, a) — f (s)\ <£.
s&K
t E [0,T] : sup \Z(s + iT, a) — p(s)\ <-
s&K 2
12)
}
{
c t e [0, T] : sup\Z(s + iT, a) — f (s)\ < -
s&K 2
Then, by (11),
1
liminf ^meas < t E [0,T] : sup\Z(s + iT; a) — f (s)\ < £ [> > 0.
T^ T { s&K
. )
The theorem is proved.
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Шяуляйский университет, Литва.
Siauliai University, Lithuania. Получено 12.09.2014
