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Main Authors: Mehraban, Saeed, Tahmasbi, Mehrdad
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.24202
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author Mehraban, Saeed
Tahmasbi, Mehrdad
author_facet Mehraban, Saeed
Tahmasbi, Mehrdad
contents Stabilizer states are fundamental families of quantum states with crucial applications such as error correction, quantum computation, and simulation of quantum circuits. In this paper, we study the problem of testing how close or far a quantum state is to a stabilizer state. We make two contributions: First, we improve the state-of-the-art parameters for the tolerant testing of stabilizer states. In particular, we show that there is an efficient quantum primitive to distinguish if the maximum fidelity of a quantum state with a stabilizer state is $\geq ε_1$ or $\leq ε_2$, given one of them is the case, provided that $ε_2 \leq ε_1^{O(1)}$. This result improves the parameters in the previous work [AD24] which assumed $ε_2 \leq e^{- 1/ε^{O(1)}_1}$ [AD24]. Our proof technique extends the toolsets developed in [AD24] by applying a random Clifford map which balances the characteristic function of a quantum state, enabling the use of standard proof techniques from higher-order Fourier analysis for Boolean functions [HHL19, Sam07], where improved testing bounds are available. Second, we study the problem of testing low stabilizer rank states. We show that if for an infinite family of quantum states stabilizer rank is lower than a constant independent of system size, then stabilizer fidelity is lower bounded by an absolute constant. Using a result of [GIKL22], one of the implications of this result is that low approximate stabilizer rank states are not pseudo-random. At the same time our work was completed and posted on arXiv, two other groups [BvDH24, ABD24] independently achieved similar exponential to polynomial improvements for tolerant testing, each using a different approach.
format Preprint
id arxiv_https___arxiv_org_abs_2410_24202
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Improved bounds for testing low stabilizer complexity states
Mehraban, Saeed
Tahmasbi, Mehrdad
Quantum Physics
Stabilizer states are fundamental families of quantum states with crucial applications such as error correction, quantum computation, and simulation of quantum circuits. In this paper, we study the problem of testing how close or far a quantum state is to a stabilizer state. We make two contributions: First, we improve the state-of-the-art parameters for the tolerant testing of stabilizer states. In particular, we show that there is an efficient quantum primitive to distinguish if the maximum fidelity of a quantum state with a stabilizer state is $\geq ε_1$ or $\leq ε_2$, given one of them is the case, provided that $ε_2 \leq ε_1^{O(1)}$. This result improves the parameters in the previous work [AD24] which assumed $ε_2 \leq e^{- 1/ε^{O(1)}_1}$ [AD24]. Our proof technique extends the toolsets developed in [AD24] by applying a random Clifford map which balances the characteristic function of a quantum state, enabling the use of standard proof techniques from higher-order Fourier analysis for Boolean functions [HHL19, Sam07], where improved testing bounds are available. Second, we study the problem of testing low stabilizer rank states. We show that if for an infinite family of quantum states stabilizer rank is lower than a constant independent of system size, then stabilizer fidelity is lower bounded by an absolute constant. Using a result of [GIKL22], one of the implications of this result is that low approximate stabilizer rank states are not pseudo-random. At the same time our work was completed and posted on arXiv, two other groups [BvDH24, ABD24] independently achieved similar exponential to polynomial improvements for tolerant testing, each using a different approach.
title Improved bounds for testing low stabilizer complexity states
topic Quantum Physics
url https://arxiv.org/abs/2410.24202