@article{ajams2014221,
author={Mazurkin, P.M.},
title={Proof the Riemann Hypothesis},
journal={American Journal of Applied Mathematics and Statistics},
volume={2},
number={2},
pages={53--59},
year={2014},
url={http://pubs.sciepub.com/ajams/2/2/1},
issn={2333-4576},
abstract={In the proof of the correctness of the Riemann hypothesis held strong Godel's incompleteness theorem. In keeping with the ideas of Poja and Hadamard's mathematical inventions, we decided to go beyond the modern achievements of the Gauss law of prime numbers and Riemann transformations in the complex numbers, knowing that at equipotent prime natural numbers will be sufficient mathematical transformations in real numbers. In simple numbers on the top left corner of the incidence matrix blocks are of the frame. When they move, a jump of the prime rate. Capacity of a number of prime numbers can be controlled by a frame, and they will be more reliable digits. In the column i=1 there is only one non-trivial zero on j=(0,&#8734;). By the implicit Gaussian "normal" distribution <img src=image/abs1.png></img>, where  P<SUB>j</SUB> - a number of prime numbers with the order-rank j. On the critical line of the formula for prime numbers <img src=image/abs2.png></img>. By "the famous Riemann hypothesis is that the real part of the root is always exactly equal to 1/2" is obtained - the vibration frequency of a series of prime numbers is equal <span style="font-family:Times New Roman; font-size:16px;">&#960;</span>/2, and the shift of the wave - <span style="font-family:Times New Roman; font-size:16px;">&#960;</span>/4.},
doi={10.12691/ajams-2-2-1}
publisher={Science and Education Publishing}
}