Utilizing a Novel Universal Quantum Gate in the Design of Fault-Tolerant Architecture

IF 2.9 4区 计算机科学 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC Nano Communication Networks Pub Date : 2023-12-02 DOI:10.1016/j.nancom.2023.100482
Neeraj Kumar Misra , Bandan Kumar Bhoi , Sankit Ramkrishna Kassa
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Abstract

In nano communication, fault-tolerant networks play a crucial role in error control. A significant practical challenge for nanocircuits is their ability to transmit information over networks to different endpoints. Fault-tolerant and reversible circuits have control error problems. The advantage of a quantum gate-based architecture is that it prevents heat loss, and it has been extensively researched. In this article, we have developed reversible multiplexers (mux's), half-adder (HA), and full-adder (FA) and latches that are fault-tolerant by making use of new gate and implementing them on the IBM Qiskit platform. A power-efficient and fault-tolerant mux's and latches is proposed that uses reversible gates to preserve parity. Multiplexer kinds such as 2:1, 4:1, and n:1 is covered in depth by the new Parity Preserving Multiplexer (PPM) gate and verified by IBM-Qiskit. An algorithmic design for an n:1 multiplexer is invented. In order to assess a PPM gate effectiveness, 13 standard Boolean functions and 8 standard types of gates are implemented. The PPM quantum gate is built using quantum assembly code (QAC), which runs on IBM Quantum Lab and IBM Quantum Composer platforms to measure the output qubits. Additional HA, muxes, and latches design led to the code creation in the Qiskit platform, which was used to measure the output qubits. A comparison of the D-latch, T-latch, JK-latch, and mux designs with existing circuits shows a reduction in quantum cost (qc) and junk output (go) and the implementation of a custom design in the IBM-Qiskit platform to measure output qubits is a first time in literature.

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一种新型通用量子门在容错架构设计中的应用
在纳米通信中,容错网络在错误控制中起着至关重要的作用。纳米电路的一个重要的实际挑战是它们通过网络向不同端点传输信息的能力。容错可逆电路存在控制误差问题。基于量子门的结构的优点是它可以防止热损失,并且已经被广泛研究。在本文中,我们开发了可逆多路复用器(mux’s)、半加法器(HA)、全加法器(FA)和锁存器,通过使用新的门并在IBM Qiskit平台上实现它们,它们具有容错性。提出了一种利用可逆门保持奇偶性的低功耗容错多路锁存器。新的奇偶保持复用器(PPM)门将深入介绍2:1、4:1和n:1等多路复用器类型,并由IBM-Qiskit进行验证。提出了一种n:1多路复用器的算法设计。为了评估PPM门的有效性,实现了13个标准布尔函数和8种标准类型的门。PPM量子门是使用量子汇编代码(QAC)构建的,它在IBM量子实验室和IBM量子作曲家平台上运行,以测量输出量子位。额外的HA、互斥器和锁存器设计导致在Qiskit平台上创建代码,用于测量输出量子位。d锁存器、t锁存器、jk锁存器和复用器设计与现有电路的比较表明,量子成本(qc)和垃圾输出(go)降低,并且在IBM-Qiskit平台上实现定制设计来测量输出量子位,这在文献中是第一次。
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来源期刊
Nano Communication Networks
Nano Communication Networks Mathematics-Applied Mathematics
CiteScore
6.00
自引率
6.90%
发文量
14
期刊介绍: The Nano Communication Networks Journal is an international, archival and multi-disciplinary journal providing a publication vehicle for complete coverage of all topics of interest to those involved in all aspects of nanoscale communication and networking. Theoretical research contributions presenting new techniques, concepts or analyses; applied contributions reporting on experiences and experiments; and tutorial and survey manuscripts are published. Nano Communication Networks is a part of the COMNET (Computer Networks) family of journals within Elsevier. The family of journals covers all aspects of networking except nanonetworking, which is the scope of this journal.
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