Fast quantum algorithms for trace distance estimation

Qisheng Wang; Zhicheng Zhang

doi:10.48550/arXiv.2301.06783

Fast quantum algorithms for trace distance estimation

Qisheng Wang^*, Zhicheng Zhang

^*Corresponding author for this work

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

Abstract

In quantum information, trace distance is a basic metric of distinguishability between quantum states. However, there is no known efficient approach to estimate the value of trace distance in general. In this paper, we propose efficient quantum algorithms for estimating the trace distance within additive error ε between mixed quantum states of rank r. Specifically, we first provide a quantum algorithm using r⋅O˜(1/ε2) queries to the quantum circuits that prepare the purifications of quantum states. Then, we modify this quantum algorithm to obtain another algorithm using O˜(r2/ε5) samples of quantum states, which can be applied to quantum state certification. These algorithms have query/sample complexities that are independent of the dimension N of quantum states, and their time complexities only incur an extra O(log(N)) factor. In addition, we show that the decision version of low-rank trace distance estimation is BQP-complete.

Original language	English
Pages (from-to)	1-14
Number of pages	14
Journal	IEEE Transactions on Information Theory
Volume	70
Issue number	4
DOIs	https://doi.org/10.48550/arXiv.2301.06783 https://doi.org/10.1109/TIT.2023.3321121
Publication status	Published - 2 Oct 2023

Keywords / Materials (for Non-textual outputs)

quantum algorithms
trace distance
singular value decomposition
Hadamard test

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title = "Fast quantum algorithms for trace distance estimation",

abstract = "In quantum information, trace distance is a basic metric of distinguishability between quantum states. However, there is no known efficient approach to estimate the value of trace distance in general. In this paper, we propose efficient quantum algorithms for estimating the trace distance within additive error ε between mixed quantum states of rank r. Specifically, we first provide a quantum algorithm using r⋅O˜(1/ε2) queries to the quantum circuits that prepare the purifications of quantum states. Then, we modify this quantum algorithm to obtain another algorithm using O˜(r2/ε5) samples of quantum states, which can be applied to quantum state certification. These algorithms have query/sample complexities that are independent of the dimension N of quantum states, and their time complexities only incur an extra O(log(N)) factor. In addition, we show that the decision version of low-rank trace distance estimation is BQP-complete.",

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author = "Qisheng Wang and Zhicheng Zhang",

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T1 - Fast quantum algorithms for trace distance estimation

AU - Wang, Qisheng

AU - Zhang, Zhicheng

PY - 2023/10/2

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N2 - In quantum information, trace distance is a basic metric of distinguishability between quantum states. However, there is no known efficient approach to estimate the value of trace distance in general. In this paper, we propose efficient quantum algorithms for estimating the trace distance within additive error ε between mixed quantum states of rank r. Specifically, we first provide a quantum algorithm using r⋅O˜(1/ε2) queries to the quantum circuits that prepare the purifications of quantum states. Then, we modify this quantum algorithm to obtain another algorithm using O˜(r2/ε5) samples of quantum states, which can be applied to quantum state certification. These algorithms have query/sample complexities that are independent of the dimension N of quantum states, and their time complexities only incur an extra O(log(N)) factor. In addition, we show that the decision version of low-rank trace distance estimation is BQP-complete.

AB - In quantum information, trace distance is a basic metric of distinguishability between quantum states. However, there is no known efficient approach to estimate the value of trace distance in general. In this paper, we propose efficient quantum algorithms for estimating the trace distance within additive error ε between mixed quantum states of rank r. Specifically, we first provide a quantum algorithm using r⋅O˜(1/ε2) queries to the quantum circuits that prepare the purifications of quantum states. Then, we modify this quantum algorithm to obtain another algorithm using O˜(r2/ε5) samples of quantum states, which can be applied to quantum state certification. These algorithms have query/sample complexities that are independent of the dimension N of quantum states, and their time complexities only incur an extra O(log(N)) factor. In addition, we show that the decision version of low-rank trace distance estimation is BQP-complete.

KW - quantum algorithms

KW - trace distance

KW - singular value decomposition

KW - Hadamard test

U2 - 10.48550/arXiv.2301.06783

DO - 10.48550/arXiv.2301.06783

M3 - Article

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VL - 70

SP - 1

EP - 14

JO - IEEE Transactions on Information Theory

JF - IEEE Transactions on Information Theory

IS - 4

ER -

Fast quantum algorithms for trace distance estimation

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