伪量子纠缠并不便宜

arXiv - CS - Computational Complexity Pub Date : 2024-03-29 DOI:arxiv-2404.00126

Sabee Grewal, Vishnu Iyer, William Kretschmer, Daniel Liang

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引用次数: 0

摘要

我们证明，任何具有 $t$ 比特熵间隙的伪纠缠态集合都需要 $\Omega(t)$ 非克里福德门来准备。如果存在线性时间量子安全伪随机函数，那么这个约束会紧缩到多对数因子。我们的结果来自于一种多项式时间算法，它可以估算量子态在任意量子比特切割时的纠缠熵。当在一个至少由2^{n-t}$保利奥佩尔器稳定的$n$量子比特态上运行时，我们的算法产生的估算结果与真实纠缠熵的比特数在一个加系数$frac{t}{2}$之内。

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Pseudoentanglement Ain't Cheap

We show that any pseudoentangled state ensemble with a gap of $t$ bits of entropy requires $\Omega(t)$ non-Clifford gates to prepare. This bound is tight up to polylogarithmic factors if linear-time quantum-secure pseudorandom functions exist. Our result follows from a polynomial-time algorithm to estimate the entanglement entropy of a quantum state across any cut of qubits. When run on an $n$-qubit state that is stabilized by at least $2^{n-t}$ Pauli operators, our algorithm produces an estimate that is within an additive factor of $\frac{t}{2}$ bits of the true entanglement entropy.

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arXiv - CS - Computational Complexity

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