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Main Authors: Li, Xinpeng, Liu, Ji, Larson, Jeffrey M., Xu, Shuai, Iyengar, Sundararaja Sitharama, Hovland, Paul, Chaudhary, Vipin
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.05722
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author Li, Xinpeng
Liu, Ji
Larson, Jeffrey M.
Xu, Shuai
Iyengar, Sundararaja Sitharama
Hovland, Paul
Chaudhary, Vipin
author_facet Li, Xinpeng
Liu, Ji
Larson, Jeffrey M.
Xu, Shuai
Iyengar, Sundararaja Sitharama
Hovland, Paul
Chaudhary, Vipin
contents Quantum circuits can be reduced through optimization to better fit the constraints of quantum hardware. One such method, initial-state dependent optimization (ISDO), reduces gate count by leveraging knowledge of the input quantum states. Surprisingly, we found that ISDO is broadly applicable to the downstream circuits produced by circuit cutting. Circuit cutting also requires measuring upstream qubits and has some flexibility of selection observables to do reconstruction. Therefore, we propose a state-dependent optimization (SDO) framework that incorporates ISDO, our newly proposed measure-state dependent optimization (MSDO), and a biased observable selection strategy. Building on the strengths of the SDO framework and recognizing the scalability challenges of circuit cutting, we propose non-separate circuit cutting-a more flexible approach that enables optimizing gates without fully separating them. We validate our methods on noisy simulations of QAOA, QFT, and BV circuits. Results show that our approach consistently mitigates noise and improves overall circuit performance, demonstrating its promise for enhancing quantum algorithm execution on near-term hardware.
format Preprint
id arxiv_https___arxiv_org_abs_2506_05722
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle State Dependent Optimization with Quantum Circuit Cutting
Li, Xinpeng
Liu, Ji
Larson, Jeffrey M.
Xu, Shuai
Iyengar, Sundararaja Sitharama
Hovland, Paul
Chaudhary, Vipin
Quantum Physics
Quantum circuits can be reduced through optimization to better fit the constraints of quantum hardware. One such method, initial-state dependent optimization (ISDO), reduces gate count by leveraging knowledge of the input quantum states. Surprisingly, we found that ISDO is broadly applicable to the downstream circuits produced by circuit cutting. Circuit cutting also requires measuring upstream qubits and has some flexibility of selection observables to do reconstruction. Therefore, we propose a state-dependent optimization (SDO) framework that incorporates ISDO, our newly proposed measure-state dependent optimization (MSDO), and a biased observable selection strategy. Building on the strengths of the SDO framework and recognizing the scalability challenges of circuit cutting, we propose non-separate circuit cutting-a more flexible approach that enables optimizing gates without fully separating them. We validate our methods on noisy simulations of QAOA, QFT, and BV circuits. Results show that our approach consistently mitigates noise and improves overall circuit performance, demonstrating its promise for enhancing quantum algorithm execution on near-term hardware.
title State Dependent Optimization with Quantum Circuit Cutting
topic Quantum Physics
url https://arxiv.org/abs/2506.05722