Quantum Combinational Logics and their Realizations with Circuits

Tong, Xiaoxue; Chen, Tian; Pan, Naiqiao; Zhang, Xiangdong

doi:10.1002/qute.202300251

Adv Quantum Tech

2023

DOI: 10.1002/qute.202300251

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Quantum Combinational Logics and their Realizations with Circuits

Xiaoxue Tong,

Tian Chen,

Naiqiao Pan

et al.

Abstract: Classical combinational logic circuits (CCLCs) are widely used in various fields. Corresponding to the CCLCs, here schemes are given for some quantum combinational logic circuits (QCLCs) based on the quantum NAND tree. Three typical circuits, adder, comparator, and seven‐segment display decoder, are discussed in detail as examples. All the designs of the schemes are based on the quantum random walk theory. Furthermore, these QCLCs are mapped onto the classical circuit networks and design new types of CCLCs, an… Show more

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2024

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Cited by 2 publications

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Research

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Game theory problems are widely applied in many research areas such as computer science and finance, with the key issue being how to quickly make decisions. Here, we present a novel quantum algorithm for game theory problems based on a continuous quantum walk. Our algorithm exhibits quantum advantage compared to classical game algorithms. Furthermore, we exploit the analogy between the wave function of the Schrödinger equation and the voltage in Kirchhoff’s law to effectively translate the design of quantum game trees into classical circuit networks. We have theoretically simulated the quantum game trees and experimentally validated the quantum functionality speedup on classical circuit networks. Due to the robust scalability and stability inherent in classical circuit networks, quantum game trees implemented within this framework hold promise for addressing more intricate application scenarios.

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Quantum Combinational Logics and their Realizations with Circuits

Cited by 2 publications

References 34 publications

Circuit realization of topological physics

Circuit realization of topological physics

Quantum 2-Player Games and Realizations with Circuits

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