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Main Authors: Xu, Liang, Zhou, Mingti, Tao, Runxia, Zhong, Zhipeng, Wang, Ben, Cao, Zhiyong, Xia, Hongkuan, Wang, Qianyi, Zhan, Hao, Zhang, Aonan, Yu, Shang, Xu, Nanyang, Dong, Ying, Ren, Changliang, Zhang, Lijian
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2303.06903
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author Xu, Liang
Zhou, Mingti
Tao, Runxia
Zhong, Zhipeng
Wang, Ben
Cao, Zhiyong
Xia, Hongkuan
Wang, Qianyi
Zhan, Hao
Zhang, Aonan
Yu, Shang
Xu, Nanyang
Dong, Ying
Ren, Changliang
Zhang, Lijian
author_facet Xu, Liang
Zhou, Mingti
Tao, Runxia
Zhong, Zhipeng
Wang, Ben
Cao, Zhiyong
Xia, Hongkuan
Wang, Qianyi
Zhan, Hao
Zhang, Aonan
Yu, Shang
Xu, Nanyang
Dong, Ying
Ren, Changliang
Zhang, Lijian
contents Sequential weak measurements allow the direct extraction of individual density-matrix elements instead of globally reconstructing the whole density matrix, opening a new avenue for the characterization of quantum systems. Nevertheless, the requirement of multiple coupling for each qudit of quantum systems and the lack of appropriate precision evaluation constraint its applicability extension, especially for multi-qudit quantum systems. Here, we propose a resource-efficient scheme (RES) to directly characterize the density matrix of general multi-qudit systems, which not only optimizes the measurements but also establishes a feasible estimation analysis. In this scheme, an efficient observable of quantum system is constructed such that a single meter state coupled to each qudit is sufficient to extract the corresponding density-matrix element. An appropriate model based on the statistical distribution of errors are used to evaluate the precision and feasibility of the scheme. We experimentally apply the RES to the direct characterization of general single-photon qutrit states and two-photon entangled states. The results show that the RES outperforms the sequential schemes in terms of efficiency and precision in both weak- and strong- coupling scenarios. This work sheds new light on the practical characterization of large-scale quantum systems and investigation of their non-classical properties.
format Preprint
id arxiv_https___arxiv_org_abs_2303_06903
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Resource-efficient Direct Characterization of General Density Matrix
Xu, Liang
Zhou, Mingti
Tao, Runxia
Zhong, Zhipeng
Wang, Ben
Cao, Zhiyong
Xia, Hongkuan
Wang, Qianyi
Zhan, Hao
Zhang, Aonan
Yu, Shang
Xu, Nanyang
Dong, Ying
Ren, Changliang
Zhang, Lijian
Quantum Physics
Optics
Sequential weak measurements allow the direct extraction of individual density-matrix elements instead of globally reconstructing the whole density matrix, opening a new avenue for the characterization of quantum systems. Nevertheless, the requirement of multiple coupling for each qudit of quantum systems and the lack of appropriate precision evaluation constraint its applicability extension, especially for multi-qudit quantum systems. Here, we propose a resource-efficient scheme (RES) to directly characterize the density matrix of general multi-qudit systems, which not only optimizes the measurements but also establishes a feasible estimation analysis. In this scheme, an efficient observable of quantum system is constructed such that a single meter state coupled to each qudit is sufficient to extract the corresponding density-matrix element. An appropriate model based on the statistical distribution of errors are used to evaluate the precision and feasibility of the scheme. We experimentally apply the RES to the direct characterization of general single-photon qutrit states and two-photon entangled states. The results show that the RES outperforms the sequential schemes in terms of efficiency and precision in both weak- and strong- coupling scenarios. This work sheds new light on the practical characterization of large-scale quantum systems and investigation of their non-classical properties.
title Resource-efficient Direct Characterization of General Density Matrix
topic Quantum Physics
Optics
url https://arxiv.org/abs/2303.06903