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IJSTR >> Volume 9 - Issue 3, March 2020 Edition

International Journal of Scientific & Technology Research  
International Journal of Scientific & Technology Research

Website: http://www.ijstr.org

ISSN 2277-8616

Design And Simulation Of Quantum Adder Using Ibm Quantum Experience

[Full Text]



G.Ravivarma, K.Gavaskar, N.S.Kavitha



Full Adder, Moore’s Law, Qubit, Quantum computing, Quantum gates, Quantum mechanics.



The use of unique quantum mechanical properties, such as superposition and entanglement, makes the quantum machines used to carry out operations with information. The fundamental theory of quantum computation is that the quantum belongings of particles can be used to symbolize and organize data. In conventional system, there are only two possible states either 1 or 0 that is stored in memory cells. But in the case of quantum system, the so called qubit, which holds 1 or 0 or a superposition of both. Moore who has predicted that quantity of transistors gets doubled for every 18 months in an IC. Now 5 nm node is the technology node followed by 7nm. Classical adder is made of CMOS transistor, further shrinking leads to quantum behavior as it is limited by the phenomena called quantum tunneling. Like classical gates such as OR, AND, NOT, NOR, NAND, EXOR, whereas in quantum, make use of X gate, Hadamard (H) gate, Z gate, S gate, T gate, Toffoli (CCNOT) gate. Operations like addition, subtraction, multiplication, etc can be done in quantum computing. The proposed quantum full adder is designed and simulated in IBM quantum experience.



[1]. K. Gavaskar and U.S. Ragupathy, “Low Power Self-Controllable Voltage Level and Low Swing Logic Based 11T SRAM Cell for High Speed CMOS Circuits,” Analog Integrated Circuits and Signal Processing, Springer, volume 100, issue 1, pp.61-77, (July 2019).
[2]. K. Gavaskar, U.S. Ragupathy and V. Malini, “Design of Novel SRAM Cell using Hybrid VLSI Techniques for Low Leakage and High Speed in Embedded Memories,” Wireless Personal Communications, Springer, volume 108, issue 4, pp.2311-2339, (October 2019).
[3]. https://quantum-computing.ibm.com/ - IBM Q Experience
[4]. M. Nielsen and I. Chuang, “Quantum Computation and Quantum Information,” Cambridge University Press, (2000).
[5]. M. Oszmaniec, A. Grudka, M. Horodecki, et al. “Creating a Superposition of Unknown Quantum States,” Physical review letters, (2016).
[6]. C. Zu, W.B. Wang, L. He, et al. “Experimental Realization of Universal Geometric Quantum Gates with Solid-State Spins,” Nature 514, 72–75 (2014).
[7]. G.H. Low, T.J. Yoder, and Isaac L. Chuang “Methodology of Resonant Equiangular Composite Quantum Gates,” The American Physical Society. X 6, 041067 (2016).
[8]. R. Li, U. Alvarez-Rodriguez, L. Lamata, et al. “Approximate Quantum Adders with Genetic Algorithms: An IBM Quantum Experience,” Quantum Meas. Quantum Metrol. 4, 1–7 (2017)
[9]. J.R. Mohammad and K. Navi, “A Novel Reversible Adder/Subtractor with Overflow Detection,” Journal of Computational and Theoretical Nanoscience, Volume 13, No. 7, pp. 4050-4055, (2016)
[10]. U. Alvarez-Rodriguez, M. Sanz, L. Lamata, et al. “The Forbidden Quantum Adder”, Scientific reports, nature, (2015)