SYNTHESIS OF MAJORITY SINGLE-ELECTRON NANODEVICES WITH MEMORY

Authors

  • O. S. Melnyk National Aviation University, Kyiv
  • Y. V. Poliakov National Aviation University, Kyiv

DOI:

https://doi.org/10.18372/1990-5548.61.14218

Keywords:

majority element, sequential nanodevices, quantum automata, one-electronics, computer aided design

Abstract

The paper describes the synthesis of reliable sequential nanodevices based on the single-electronics technology of quantum cellular automata. When constructing majority nanocircuits with memory, the theory of finite automata is used. The order of computer design of different types of arithmetic and logic nano-devices is analyzed. Fundamentals of large-logical arithmetic nanocircuit based on multi-narrative selection of unique trigger majority of components on the basis of quantum cellular automata. This creates the preconditions for adaptive implementation of these nanoscales in modern computerized telecommunication systems.

Author Biographies

O. S. Melnyk, National Aviation University, Kyiv

Electronic Department, Faculty of Air Navigation, Electronics & Telecommunications

Candidate of Science (Engendering). Associate Professor

orcid.org/0000-0003-1072-5526

Y. V. Poliakov, National Aviation University, Kyiv

Electronic Department, Faculty of Air Navigation, Electronics & Telecommunications

Student

References

C. S. Lent and P. D. Tougaw, “Devices Architecture for Computing whith Quantium Dots,” Proc. of the IEEE, vol. 10, no. 3, 1997, pp. 73–83.

A. Vetteth, “RAM design using QCA,” Proc. of 2013 Nanotechn. Conf. and Trade show, vol. 2, pp. 160–168.

D. Berzon, “A memory design in QCA,” Proc. IX-th Symp. At VLST, 2009.

S. Frost, “Memory in motion: study of Storage in QCA,” First work. on nonsilicon computing, 2012.

M. Ottavi, “Tile-based design of a serial memory in QCA,” Proc. of 15-th ACM Symp. on VLST, April, 2008.

N. I. Pakulov, The majority principle of building reliable nodes and devices.: Sov. radio, 1974, 184 p. (in Russian).

O. S. Melnyk and S. O. Todavchych, “Synthesis of Programmable Nanoelectronic Devices,” Electronic and Control Systems. no. 4 (32), pp. 89–94, 2013.

K. Walus, “QCA Designer: A Rapid Design and Simulation Tool to QCADII,” Int. Journal of Nanotech and Appl., no. 1, pp. 1–7, 2005.

Downloads

Issue

Section

COMPUTER-AIDED DESIGN SYSTEMS