Design and Implementation of Multi-operative Reversible Gate for Even/Odd Parity Generators in Quantum based Technologies

Puspak Pain; Arindam Sadhu; Kunal Das; Maitreyi Ray Kanjilal

doi:10.57159/gadl.jcmm.2.4.23084

Authors

Puspak Pain PhD. Cell, Department of Electronics and Communication Engineering, Maulana Abul Kalam Azad University of Technology, Haringhata, Nadia, West Bengal, India 741249
Arindam Sadhu Department of Electronics and Communication Engineering, Greater Kolkata College of Engineering and Management, Baruipur, West Bengal, India 743387
Kunal Das Department of Computer Science, Acharya Prafulla Chandra College, West Bengal State University, Kolkata, West Bengal, India 700131
Maitreyi Ray Kanjilal Victoria Institution (College), Calcutta University, West Bengal, India, Kolkata 700009

DOI:

https://doi.org/10.57159/gadl.jcmm.2.4.23084

Keywords:

Multi-operative, Reversible Circuit, Even/Odd Parity Generator, Nano-Communication, Quantum Technologies

Abstract

Quantum technology is graciously budding in nano-communication due to its properties and logical function, having the momentous prosperity of being reversible. It has gained an appeal to future-generation research owing to those sole aspects that may not be explored in the classical realm. A reliable nano-communication system utilizes varied error detection and correction techniques. Beyond low device density, authentic random number generation is a crucial issue in the cryptographic aspects of future communication architecture. To our knowledge, this is the innate study of an intriguing prospect: the design and implementation based on the lower level of power 'even/odd parity generator' using a single multi-operative reversible gate that has been achieved and functionally authenticated in the QCA nanotechnology, likewise in the IBMQ experience allied to quantum-based technologies. This breakthrough in nanotechnology and quantum-based technologies could have significant implications for blooming more efficient, secure communication systems in post-quantum cryptography.

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