Quantum Information and the PCP Theorem
Abstract
We show how to encode (classical) bits by a single quantum state of size O(n) qubits, such that: for any constant and any , the values of the bits can be retrieved from by a one-round Arthur-Merlin interactive protocol of size polynomial in . This shows how to go around Holevo-Nayak's Theorem, using Arthur-Merlin proofs. We use the new representation to prove the following results: 1) Interactive proofs with quantum advice: We show that the class contains ALL languages. That is, for any language (even non-recursive), the membership (for of length ) can be proved by a polynomial-size quantum interactive proof, where the verifier is a polynomial-size quantum circuit with working space initiated with some quantum state (depending only on and ). Moreover, the interactive proof that we give is of only one round, and the messages communicated are classical. 2) PCP with only one query: We show that the membership (for of length ) can be proved by a logarithmic-size quantum state , together with a polynomial-size classical proof consisting of blocks of length bits each, such that after measuring the state the verifier only needs to read {\bf one} block of the classical proof. While the first result is a straight forward consequence of the new representation, the second requires an additional machinery of quantum low-degree-test that may be interesting in its own right.
Cite
@article{arxiv.quant-ph/0504075,
title = {Quantum Information and the PCP Theorem},
author = {Ran Raz},
journal= {arXiv preprint arXiv:quant-ph/0504075},
year = {2007}
}
Comments
30 pages