English

Quantum Information and the PCP Theorem

Quantum Physics 2007-05-23 v1

Abstract

We show how to encode 2n2^n (classical) bits a1,...,a2na_1,...,a_{2^n} by a single quantum state Ψ>|\Psi> of size O(n) qubits, such that: for any constant kk and any i1,...,ik{1,...,2n}i_1,...,i_k \in \{1,...,2^n\}, the values of the bits ai1,...,aika_{i_1},...,a_{i_k} can be retrieved from Ψ>|\Psi> by a one-round Arthur-Merlin interactive protocol of size polynomial in nn. 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 QIP/qpolyQIP/qpoly contains ALL languages. That is, for any language LL (even non-recursive), the membership xLx \in L (for xx of length nn) 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 ΨL,n>|\Psi_{L,n} > (depending only on LL and nn). 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 xSATx \in SAT (for xx of length nn) can be proved by a logarithmic-size quantum state Ψ>|\Psi >, together with a polynomial-size classical proof consisting of blocks of length polylog(n)polylog(n) bits each, such that after measuring the state Ψ>|\Psi > 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}
}

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30 pages