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Bibliographic Details
Main Authors: Nakamura, Junya, Satoh, Takahiko, Sanji, Shinichiro
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.18031
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author Nakamura, Junya
Satoh, Takahiko
Sanji, Shinichiro
author_facet Nakamura, Junya
Satoh, Takahiko
Sanji, Shinichiro
contents We propose a new method for identifying cutting locations for quantum circuit cutting, with a primary focus on partitioning circuits into three or more parts. Under the assumption that the classical postprocessing function is decomposable, we derive a new upper bound on the sampling overhead resulting from both time-like and space-like cuts. We show that this bound improves upon the previously known bound by orders of magnitude in cases of three or more partitions. Based on this bound, we formulate an objective function, $L_Q^{}$, and present a method to determine cutting locations that minimize it. Our method is shown to outperform a previous approach in terms of computation time. Moreover, the quality of the obtained partitioning is found to be comparable to or better than that of the baseline in all but a few cases, as measured by $L_Q^{}$. These results are obtained by identifying cutting locations in a number of benchmark circuits of the size and type expected in quantum computations that outperform classical computers.
format Preprint
id arxiv_https___arxiv_org_abs_2506_18031
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Improved sampling bounds and scalable partitioning for quantum circuit cutting beyond bipartitions
Nakamura, Junya
Satoh, Takahiko
Sanji, Shinichiro
Quantum Physics
We propose a new method for identifying cutting locations for quantum circuit cutting, with a primary focus on partitioning circuits into three or more parts. Under the assumption that the classical postprocessing function is decomposable, we derive a new upper bound on the sampling overhead resulting from both time-like and space-like cuts. We show that this bound improves upon the previously known bound by orders of magnitude in cases of three or more partitions. Based on this bound, we formulate an objective function, $L_Q^{}$, and present a method to determine cutting locations that minimize it. Our method is shown to outperform a previous approach in terms of computation time. Moreover, the quality of the obtained partitioning is found to be comparable to or better than that of the baseline in all but a few cases, as measured by $L_Q^{}$. These results are obtained by identifying cutting locations in a number of benchmark circuits of the size and type expected in quantum computations that outperform classical computers.
title Improved sampling bounds and scalable partitioning for quantum circuit cutting beyond bipartitions
topic Quantum Physics
url https://arxiv.org/abs/2506.18031