Design of QCA Full Adders without wire crossing

  • Abed Mostafaee Academic Center for Education, Culture and Research- Kermanshah, Iran
  • Abbas Rezaei Electrical Engineering Department, Kermanshah University of Technology, Kermanshah, Iran
  • Mohammad Mahdi Karkhanehchi Academic Center for Education, Culture and Research- Kermanshah, Iran
  • Seyed Muhammad Jamshidi Department of electronic Engineering, Kermanshah branch, Islamic Azad University, Kermanshah, Iran
Keywords: Quantum-dot Cellular Automata, QCA Cell, Full adder, Design

Abstract

In the scale of nanometer, Quantum-dot Cellular Automata (QCA) is a new technology, which utilizes the QCA cells in order to design and implement logical circuits. QCA makes it possible for us to design in Nano scale. Furthermore, in comparison to CMOS technology, it has highly low consumption power. Thus, in the future, QCA technology will be a powerful rival for VLSI. This paper presents two new and optimized QCA designs for Full adder. In comparison to the previous designs, all of the QCA Full adders presented in this paper are relatively optimized. In addition, they are implemented without any wire crossing. In order to test the proposed QCA Layouts and also display the results of the simulations, QCADesigner software is used.

Downloads

Download data is not yet available.

References

[1] Design of Analog CMOS Integrated Circuits, Behzad Razavi professor of Electrical Engineering University of California, Los Angeles, 2012.
[2] Compano R., Molenkamp L., and Paul D.J., Roadmap for Nanoelectronics, 2011.
[3] Sheikhfaal S., Angizi S., Sarmadi S., Moaiyeri M.H., Sayedsalehi S. Designing efficient QCA logical circuits with power dissipation analysis. Microelec. J. 2015; 46: 462-471.
[4] Teja V.C., Polisetti S. and Kasavajjala S. QCA based Multiplexing of 16 Arithmetic & Logical Subsystems-A paradigm for Nano Computing 2008. The 3rd IEEE Int. Conf.on Nano/Micro Engineered and Molecular Sys. 2008: 758-763.
[5] Amlani I., Orlov A.O., Toth G., Bernstein G.H., Lent C.S., Snider G.L. Digital logic gate using quantum-dot cellular automata, Science. 1999; 284: 289–291.
[6] Cho H. and Swartzlander E.E. Adder designs and analyses for quantum dot cellular automata. IEEE Trans. Nanotechnol. 2007; 6(3): 374–383.
[7] Hashemi S., Tehrani M., and Navi K. An efficient quantum-dot cellular automata full-adder. Scientific Research and Essays. 2012; 7: 177–189.
[8] Roohi A., Ronald F., Khoshavi N. Design and evaluation of an ultra-area-efficient fault-tolerant QCA full adder, Microelectronics J. 2015; 46(6): 531–542.
[9] Sen B., Rajoria A., Sikdar B.K. Design of Efficient full adder in quantum-dot cellular automata. The Scientific WorldJournal. 2013; 2013: 531–541.
[10] Sayedsalehi S., Moaiyeri M.H., Navi K. Novel efficient adder circuits for quantum-dot cellular automata. J. Comput. Theor. Nanosci 2011; 8 : 1769–1775.
[11] Roohi A., Khademolhosseini H., Sayedsalehi S., Navi K. A symmetric quantum-dot cellular automata design for 5-input majority gate, J. Comput. Electron. 2014; 13: 701–708.
[12] Navi K., Roohi A., Sayedsalehi S. Designing reconfigurable quantum-dot cellular automata logic circuits, J. Comput. Theor. Nanosci. 2013, 10: 1137–1146.
[13] Navi K., Farazkish R., Sayedsalehi S., Rahimi Azghadi M. A new quantum-dot cellular automata full-adder. Microelectron. J. 2010; 41(12): 820–826.
[14] Cho H., Swartzlander E. E. Adder and multiplier design in quantum dot cellular automata, IEEE Trans. Comput. 2009; 58: 721–727.
Published
2015-11-03
How to Cite
Mostafaee, A., Rezaei, A., Karkhanehchi, M., & Jamshidi, S. (2015). Design of QCA Full Adders without wire crossing. Boson Journal of Modern Physics, 2(2), 90-96. Retrieved from http://scitecresearch.com/journals/index.php/bjmp/article/view/413
Issue
Vol 2 No 2: BJMP
Section
Articles

Copyright (c) 2015 Boson Journal of Modern Physics

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

TRANSFER OF COPYRIGHT

BJMP is pleased to undertake the publication of your contribution to Boson Journal of Modern Physics.

The copyright to this article is transferred to BJMP(including without limitation, the right to publish the work in whole or in part in any and all forms of media, now or hereafter known) effective if and when the article is accepted for publication thus granting BJMP all rights for the work so that both parties may be protected from the consequences of unauthorized use.