A Two-Stage Solution to Quantum Process Tomography: Error Analysis and Optimal Design

Shuixin Xiao; Yuanlong Wang; Jun Zhang; Daoyi Dong; Gary J. Mooney; Ian R. Petersen; Hidehiro Yonezawa

doi:10.1109/TIT.2024.3522005

A Two-Stage Solution to Quantum Process Tomography: Error Analysis and Optimal Design

Shuixin Xiao, Yuanlong Wang^*, Jun Zhang, Daoyi Dong^*, Gary J. Mooney, Ian R. Petersen, Hidehiro Yonezawa

^*Corresponding author for this work

School of Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

Quantum process tomography is a critical task for characterizing the dynamics of quantum systems and achieving precise quantum control. In this paper, we propose a two-stage solution for both trace-preserving and non-trace-preserving quantum process tomography. Utilizing a tensor structure, our algorithm exhibits a computational complexity of O(MLd²) where d is the dimension of the quantum system and M, L(M≥ d², L≥ d²) represent the numbers of different input states and measurement operators, respectively. We establish an analytical error upper bound and then design the optimal input states and the optimal measurement operators, which are both based on minimizing the error upper bound and maximizing the robustness characterized by the condition number. Numerical examples and testing on IBM quantum devices are presented to demonstrate the performance and efficiency of our algorithm.

Original language	English
Pages (from-to)	1803-1823
Number of pages	21
Journal	IEEE Transactions on Information Theory
Volume	71
Issue number	3
DOIs	https://doi.org/10.1109/TIT.2024.3522005
Publication status	Published - 2025

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10.1109/TIT.2024.3522005

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title = "A Two-Stage Solution to Quantum Process Tomography: Error Analysis and Optimal Design",

abstract = "Quantum process tomography is a critical task for characterizing the dynamics of quantum systems and achieving precise quantum control. In this paper, we propose a two-stage solution for both trace-preserving and non-trace-preserving quantum process tomography. Utilizing a tensor structure, our algorithm exhibits a computational complexity of O(MLd2) where d is the dimension of the quantum system and M, L(M≥ d2, L≥ d2) represent the numbers of different input states and measurement operators, respectively. We establish an analytical error upper bound and then design the optimal input states and the optimal measurement operators, which are both based on minimizing the error upper bound and maximizing the robustness characterized by the condition number. Numerical examples and testing on IBM quantum devices are presented to demonstrate the performance and efficiency of our algorithm.",

keywords = "error analysis, Quantum process tomography, quantum system, quantum system identification",

author = "Shuixin Xiao and Yuanlong Wang and Jun Zhang and Daoyi Dong and Mooney, {Gary J.} and Petersen, {Ian R.} and Hidehiro Yonezawa",

note = "Publisher Copyright: {\textcopyright} 1963-2012 IEEE.",

year = "2025",

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T2 - Error Analysis and Optimal Design

AU - Xiao, Shuixin

AU - Wang, Yuanlong

AU - Zhang, Jun

AU - Dong, Daoyi

AU - Mooney, Gary J.

AU - Petersen, Ian R.

AU - Yonezawa, Hidehiro

PY - 2025

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AB - Quantum process tomography is a critical task for characterizing the dynamics of quantum systems and achieving precise quantum control. In this paper, we propose a two-stage solution for both trace-preserving and non-trace-preserving quantum process tomography. Utilizing a tensor structure, our algorithm exhibits a computational complexity of O(MLd2) where d is the dimension of the quantum system and M, L(M≥ d2, L≥ d2) represent the numbers of different input states and measurement operators, respectively. We establish an analytical error upper bound and then design the optimal input states and the optimal measurement operators, which are both based on minimizing the error upper bound and maximizing the robustness characterized by the condition number. Numerical examples and testing on IBM quantum devices are presented to demonstrate the performance and efficiency of our algorithm.

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A Two-Stage Solution to Quantum Process Tomography: Error Analysis and Optimal Design

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