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Main Authors: Jin, Yuwei, Gao, Xiangyu, Guo, Minghao, Chen, Henry, Hua, Fei, Zhang, Chi, Zhang, Eddy Z.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.11226
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author Jin, Yuwei
Gao, Xiangyu
Guo, Minghao
Chen, Henry
Hua, Fei
Zhang, Chi
Zhang, Eddy Z.
author_facet Jin, Yuwei
Gao, Xiangyu
Guo, Minghao
Chen, Henry
Hua, Fei
Zhang, Chi
Zhang, Eddy Z.
contents Rapid development in quantum computing leads to the appearance of several quantum applications. Quantum Fourier Transformation (QFT) sits at the heart of many of these applications. Existing work leverages SAT solver or heuristics to generate a hardware-compliant circuit for QFT by inserting SWAP gates to remap logical qubits to physical qubits. However, they might face problems such as long compilation time due to the huge search space for SAT solver or suboptimal outcome in terms of the number of cycles to finish all gate operations. In this paper, we propose a domain-specific hardware mapping approach for QFT. We unify our insight of relaxed ordering and unit exploration in QFT to search for a qubit mapping solution with the help of program synthesis tools. Our method is the first one that guarantees linear-depth QFT circuits for Google Sycamore, IBM heavy-hex, and the lattice surgery, with respect to the number of qubits. Compared with state-of-the-art approaches, our method can save up to 53% in SWAP gate and 92% in depth.
format Preprint
id arxiv_https___arxiv_org_abs_2408_11226
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Optimizing Quantum Fourier Transformation (QFT) Kernels for Modern NISQ and FT Architectures
Jin, Yuwei
Gao, Xiangyu
Guo, Minghao
Chen, Henry
Hua, Fei
Zhang, Chi
Zhang, Eddy Z.
Quantum Physics
Rapid development in quantum computing leads to the appearance of several quantum applications. Quantum Fourier Transformation (QFT) sits at the heart of many of these applications. Existing work leverages SAT solver or heuristics to generate a hardware-compliant circuit for QFT by inserting SWAP gates to remap logical qubits to physical qubits. However, they might face problems such as long compilation time due to the huge search space for SAT solver or suboptimal outcome in terms of the number of cycles to finish all gate operations. In this paper, we propose a domain-specific hardware mapping approach for QFT. We unify our insight of relaxed ordering and unit exploration in QFT to search for a qubit mapping solution with the help of program synthesis tools. Our method is the first one that guarantees linear-depth QFT circuits for Google Sycamore, IBM heavy-hex, and the lattice surgery, with respect to the number of qubits. Compared with state-of-the-art approaches, our method can save up to 53% in SWAP gate and 92% in depth.
title Optimizing Quantum Fourier Transformation (QFT) Kernels for Modern NISQ and FT Architectures
topic Quantum Physics
url https://arxiv.org/abs/2408.11226