Review Shop Store Quantum-Dot Cellular Automata

International Journal of VLSI & Signal Processing

© 2021 by SSRG - IJVSP Journal

Volume 8 Issue 1

Year of Publication : 2021

Authors : Yash Bishnoi , Vaibhav Gajanan Patil , Monika, Rohit Kumar Saini

10.14445/23942584/IJVSP-V8I1P101

How to Cite?

Yash Bishnoi , Vaibhav Gajanan Patil , Monika, Rohit Kumar Saini, "Review Shop Store Quantum-Dot Cellular Automata," SSRG International Journal of VLSI & Signal Processing, vol. 8,  no. 1, pp. 1-4, 2021. Crossref, https://doi.org/10.14445/23942584/IJVSP-V8I1P101

Abstract:

Quantum-dot Cellular Automata is == an upcoming futuristic technology that offers key features like high speed, low power consumption, low size, etc., are emerging nanotechnology combined with dynamic and dynamic performance wisdom. In order to test this technology, we propose a model of a logic compilation of QCA circuits. There are many studies reported on it the formation of flexible logical gates compared to the flexible TR. This paper shows the possible formation of rational exible gates of the QCA. QCADesigner is recognized for performance signs and mimics the proposed gates. In the future, these gates could be used for the construction of complex computer structures.

Keywords:

Alternative of CMOS , CMOS, Nanotechnology , QCA , Reversible Logic Gates

References:

[1] Lent, CS, Tougaw, PD, Porod, W., Bernstein, GH: Quantum mobile automata. Nanotechnology 4 (1)(1993) 49.
[2] Lent, CS, Tougaw, PD: Design of a computer-generated device with quantum dots. Procedures. IEEE 85(1997) 541- 557.
[3] Landauer, R.: Consistency and heat production in the calculation process. IBM J. Res. Dev. 5(1961) 183-191.
[4] Bennett, CH: Reasonable variability of calculation. IBM J. Res. Dev. 17(1973) 525-532.
[5] Abdullah-Al-sha_, M., Islam, M.S., Bahar, A.N: Review of _exible logic gates and implementation of QCA. Int. J. Computer. Application 128 (2)(2015) 27-34.
[6] Mohammadi, Z., Mohammadi, M .: A full-_edged one-way add-on using quantum-dot cellular automata. Quantum Inf. The process. 13(2014) 2127_2147.
[7] Cho, H., and Swartzlander, E. E. (2009). Adder and multiplier design in quantum-dot cellular automata. IEEE Transactions on Computers, 58(6) 721-727.
[8] Orlov, A.O., Amlani, I., Bernstein, G.H., Lent, C.S., Snider, G.L.: Realization of a functional cell for quantum-dot cellular automata. Science (1997). doi:10.1126/science.277.5328.928
[9] Amlani, I., Orlov, A. O., Kummamuru, R. K., Bernstein, G. H., Lent, C. S., & Snider, G. L.: Experimental demonstration of a leadless quantum-dot cellular automata cell. Appl. Phys. Lett. 77(2000) 738-740.
[10] Ling-gang, Z., Qing-kang, W., & Yong-bing, D.: A new phenomenon of quantum-dot cellular automata. Journal of Zhejiang University Science A, 6(2005) 1090-1094.
[11] Meurer, B., Heitmann, D., & Ploog, K.: Excitation of three-dimensional quantum dots. Phys. Rev. B, 48(1993) 11488.
[12] Arman, R., Hossein, K., Samira, S., Keivan, N.: A Novel Architecture for Quantum-Dot Cellular Automata Multiplexer. Int. J. Computer Science 8(2011) 55-60.
[13] Parhami, Behrooz., Fault-tolerant reversible circuits., In Signals, Systems and Computers, 2006. ACSSC'06. Fortieth Asilomar Conference on, (2006) 1726-1729. IEEE,.
[14] Walus, K., Dysart, T. J., Jullien, G. A., & Budiman, R. A.: QCADesigner: A rapid design and simulation tool for quantum-dot cellular automata. Nanotechnology, IEEE Transactions on 3(2004) 26-31.
[15] 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). doi:10. 1126/science.284.5412.289
[16] Orlov, A. O., Amlani, I., Toth, G., Lent, C. S., Bernstein, G. H., & Snider, G. L.: Experimental demonstration of a binary wire for quantum-dot cellular automata. Appl. Phys. Lett. 74(1999) 2875-2877.