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Autori principali: Zhao, Xuanqiang, Zhang, Lei, Zhao, Benchi, Wang, Xin
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2309.09963
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author Zhao, Xuanqiang
Zhang, Lei
Zhao, Benchi
Wang, Xin
author_facet Zhao, Xuanqiang
Zhang, Lei
Zhao, Benchi
Wang, Xin
contents The manipulation of quantum states through linear maps beyond quantum operations has many important applications in various areas of quantum information processing. Current methods simulate unphysical maps by sampling physical operations according to classically determined probability distributions. In this work, we show that using quantum measurement instead leads to lower simulation costs for general Hermitian-preserving maps. Remarkably, we establish the equality between the simulation cost and the well-known diamond norm, thus closing a previously known gap and assigning diamond norm a universal operational meaning for all Hermitian-preserving maps. We demonstrate our method in two applications closely related to error mitigation and quantum machine learning, where it exhibits a favorable scaling. These findings highlight the power of quantum measurement in simulating unphysical operations, in which quantum interference is believed to play a vital role. Our work paves the way for more efficient sampling techniques and has the potential to be extended to more quantum information processing scenarios.
format Preprint
id arxiv_https___arxiv_org_abs_2309_09963
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Power of quantum measurement in simulating unphysical operations
Zhao, Xuanqiang
Zhang, Lei
Zhao, Benchi
Wang, Xin
Quantum Physics
Mathematical Physics
The manipulation of quantum states through linear maps beyond quantum operations has many important applications in various areas of quantum information processing. Current methods simulate unphysical maps by sampling physical operations according to classically determined probability distributions. In this work, we show that using quantum measurement instead leads to lower simulation costs for general Hermitian-preserving maps. Remarkably, we establish the equality between the simulation cost and the well-known diamond norm, thus closing a previously known gap and assigning diamond norm a universal operational meaning for all Hermitian-preserving maps. We demonstrate our method in two applications closely related to error mitigation and quantum machine learning, where it exhibits a favorable scaling. These findings highlight the power of quantum measurement in simulating unphysical operations, in which quantum interference is believed to play a vital role. Our work paves the way for more efficient sampling techniques and has the potential to be extended to more quantum information processing scenarios.
title Power of quantum measurement in simulating unphysical operations
topic Quantum Physics
Mathematical Physics
url https://arxiv.org/abs/2309.09963