Erratum to “The Riemann Hypothesis-Millennium Prize Problem” [Advances in Pure Mathematics 6 (2016) 915-920] ()
Theorem 1. Let the function 
be limited on every finite interval, and 
(x) is
continuous and limited on every finite interval then
(1)
Corollary 1. Let the function
, 
, 
then
(2)
(3)
Our goal is to use this theorem on the analogs of zeta functions. We are interested in the analytical properties of the following generalizations of zeta functions:
(4)
(5)
(6)
(7)
Let N be the set of all natural numbers and 
―the set of all natural numbers without 
Below we will always let
, this limitation is introduced only to simplify the calculations. Considering all the information above let us rewrite
For the function 
let us apply the results obtained by Muntz for the zeta function representation. With the help of the given definitions we formulate the analog of Muntz theorem.
Lemma 1. Let the function
then (8)
![]()
(9)
PROOF: According to the theorem conditions we have
![]()
(10)
Lemma 2. Let the function
![]()
(11)
then
![]()
(12)
![]()
(13)
![]()
(14)
![]()
(15)
PROOF: Follows from computing of integrals.
Lemma 3. Let the function
![]()
, ![]()
![]()
, ![]()
then
![]()
(16)
![]()
(17)
PROOF: Computing the sums , we have
![]()
(18)
Theorem 2. Let the function
![]()
, ![]()
![]()
, ![]()
then
![]()
(19)
PROOF: Using Corollary 1. we have
![]()
(20)
![]()
(21)
![]()
(22)
![]()
(23)
![]()
(24)
![]()
(25)
From the last equation we obtain the regularity of the function ![]()
as s satisfied ![]()
Theorem 3. The Riemann’s function has nontrivial zeros only on the line![]()
;
PROOF: For![]()
, we have
![]()
(26)
Applying the formula from the theorem 2
![]()
(27)
estimating by the module
![]()
(28)
Estimating the zeta function, potentiating, we obtain
![]()
(29)
According to the theorem 1 ![]()
limited for z from the following multitude
![]()
(30)
similarly, applying the theorem 2 for ![]()
we obtain its limitation in the same multitude. For the function ![]()
we have a limitation for all z, belonging to the half-plane Re(s) > 1/2 + 1/R. similarly, applying the theorem 2 for ![]()
we obtain its limitation in the same multitude and finally we obtain:
![]()
(31)
These estimations for ![]()
prove that zate function does not have zeros on the half-plane ![]()
due to the integral representation (3) these results are projected on the half-plane ![]()
for the case of nontrivial zeros. The Riemann’s hypothesis is proved.