Quantum versus Classical Proofs and Advice

Twenty-Second Annual IEEE Conference on Computational Complexity (CCC'07) Pub Date : 2006-04-09 DOI:10.4086/toc.2007.v003a007

S. Aaronson, G. Kuperberg

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引用次数: 86

Abstract

This paper studies whether quantum proofs are more powerful than classical proofs, or in complexity terms, whether QMA = QCMA. We prove three results about this question. First, we give a "quantum oracle separation" between QMA and QCM A. More concretely, we show that any quantum algorithm needs Omega (radic2n-m+1) queries to find an n-qubit "marked state" \Psi rang, even if given an m-bit classical description of \Psi rang together with a quantum black box that recognizes \Psi rang. Second, we give an explicit QCMA protocol that nearly achieves this lower bound. Third, we show that, in the one previously-known case where quantum proofs seemed to provide an exponential advantage, classical proofs are basically just as powerful. In particular, Wa- trous gave a QM IK protocol for verifying non-membership infinite groups. Under plausible group-theoretic assumptions, we give a QCMA protocol for the same problem. Even with no assumptions, our protocol makes only poly-nomially many queries to the group oracle. We end with some conjectures about quantum versus classical oracles, and about the possibility of a classical oracle separation between QMA and QCMA.

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量子与经典的证明和建议

本文研究了量子证明是否比经典证明更强大，或者在复杂性方面，QMA是否= QCMA。关于这个问题，我们证明了三个结果。首先，我们给出了QMA和QCM a之间的“量子预言分离”，更具体地说，我们证明了任何量子算法都需要Omega (radic2n-m+1)查询来找到一个n量子位的“标记状态”\Psi范围，即使给出了\Psi范围的m位经典描述以及识别\Psi范围的量子黑箱。其次，我们给出了一个接近于这个下界的显式QCMA协议。第三，我们表明，在先前已知的量子证明似乎提供指数优势的情况下，经典证明基本上同样强大。特别地，Wa- trous给出了一个验证无限群非隶属性的qmik协议。在似是而非的群论假设下，我们给出了同样问题的QCMA协议。即使没有任何假设，我们的协议也只对组oracle进行多名义查询。最后，我们提出了一些关于量子和经典预言的猜想，以及QMA和QCMA之间经典预言分离的可能性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Twenty-Second Annual IEEE Conference on Computational Complexity (CCC'07)

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