Nearest-Neighbor and Fault-Tolerant Quantum Circuit Implementation

Laxmidhar Biswal; Chandan Bandyopadhyay; Anupam Chattopadhyay; Robert Wille; Rolf Drechsler; Hafizur Rahaman

doi:10.1109/ISMVL.2016.48

Nearest-Neighbor and Fault-Tolerant Quantum Circuit Implementation

Laxmidhar Biswal
, Chandan Bandyopadhyay
, Anupam Chattopadhyay
, Robert Wille
, Rolf Drechsler
, Hafizur Rahaman

Department of Quantum Computing

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

The quest of achieving higher computing performance is driving the research on quantum computing, which is reporting new milestones almost on a daily basis. For practical quantum circuit design, fault tolerance is an essential condition. This is achieved by mapping the target functions into the Clifford+T group of elementary quantum gates. Furthermore, the application of error-correcting codes in quantum circuits requiresthe quantum gates to be formed between adjacent Qubits. In this work, we improve the state-of-the-art quantum circuit design by addressing both of the above challenges. First, we propose a novel mapping of Multiple-Control Toffoli (MCT) gates to Clifford+T group gates, which achieves lower gate count compared to earlier work. Secondly, we show a generic way to convert any Clifford+T circuit into a nearest neighbor one. We validate the efficacy of our approach with detailed experimental studies.

Original language	English
Title of host publication	International Symposium on Multiple-Valued Logic (ISMVL)
Editors	ISMVL
Pages	156-161
Number of pages	6
ISBN (Electronic)	9781467394888
DOIs	https://doi.org/10.1109/ISMVL.2016.48
Publication status	Published - 2016

Fields of science

102 Computer Sciences
202 Electrical Engineering, Electronics, Information Engineering

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10.1109/ISMVL.2016.48

Cite this

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title = "Nearest-Neighbor and Fault-Tolerant Quantum Circuit Implementation",

abstract = "The quest of achieving higher computing performance is driving the research on quantum computing, which is reporting new milestones almost on a daily basis. For practical quantum circuit design, fault tolerance is an essential condition. This is achieved by mapping the target functions into the Clifford+T group of elementary quantum gates. Furthermore, the application of error-correcting codes in quantum circuits requiresthe quantum gates to be formed between adjacent Qubits. In this work, we improve the state-of-the-art quantum circuit design by addressing both of the above challenges. First, we propose a novel mapping of Multiple-Control Toffoli (MCT) gates to Clifford+T group gates, which achieves lower gate count compared to earlier work. Secondly, we show a generic way to convert any Clifford+T circuit into a nearest neighbor one. We validate the efficacy of our approach with detailed experimental studies.",

author = "Laxmidhar Biswal and Chandan Bandyopadhyay and Anupam Chattopadhyay and Robert Wille and Rolf Drechsler and Hafizur Rahaman",

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AU - Biswal, Laxmidhar

AU - Bandyopadhyay, Chandan

AU - Chattopadhyay, Anupam

AU - Wille, Robert

AU - Drechsler, Rolf

AU - Rahaman, Hafizur

PY - 2016

Y1 - 2016

N2 - The quest of achieving higher computing performance is driving the research on quantum computing, which is reporting new milestones almost on a daily basis. For practical quantum circuit design, fault tolerance is an essential condition. This is achieved by mapping the target functions into the Clifford+T group of elementary quantum gates. Furthermore, the application of error-correcting codes in quantum circuits requiresthe quantum gates to be formed between adjacent Qubits. In this work, we improve the state-of-the-art quantum circuit design by addressing both of the above challenges. First, we propose a novel mapping of Multiple-Control Toffoli (MCT) gates to Clifford+T group gates, which achieves lower gate count compared to earlier work. Secondly, we show a generic way to convert any Clifford+T circuit into a nearest neighbor one. We validate the efficacy of our approach with detailed experimental studies.

AB - The quest of achieving higher computing performance is driving the research on quantum computing, which is reporting new milestones almost on a daily basis. For practical quantum circuit design, fault tolerance is an essential condition. This is achieved by mapping the target functions into the Clifford+T group of elementary quantum gates. Furthermore, the application of error-correcting codes in quantum circuits requiresthe quantum gates to be formed between adjacent Qubits. In this work, we improve the state-of-the-art quantum circuit design by addressing both of the above challenges. First, we propose a novel mapping of Multiple-Control Toffoli (MCT) gates to Clifford+T group gates, which achieves lower gate count compared to earlier work. Secondly, we show a generic way to convert any Clifford+T circuit into a nearest neighbor one. We validate the efficacy of our approach with detailed experimental studies.

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DO - 10.1109/ISMVL.2016.48

M3 - Conference proceedings

SN - 978-1-4673-9488-8

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EP - 161

BT - International Symposium on Multiple-Valued Logic (ISMVL)

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ER -

Nearest-Neighbor and Fault-Tolerant Quantum Circuit Implementation

Abstract

Fields of science

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