Pointer Quantum PCPs and MultiProver Games
Grilo, Alex B. and Kerenidis, Iordanis and Pereszlényi, Attila (2016) Pointer Quantum PCPs and MultiProver Games. In: 41st International Symposium on Mathematical Foundations of Computer Science, MFCS 2016. Schloss Dagstuhl LeibnizZentrum für Informatik, Dagstuhl, 21:121:14. ISBN 9783959770163 10.4230/LIPIcs.MFCS.2016.21

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Abstract
The quantum PCP (QPCP) conjecture states that all problems in QMA, the quantum analogue of NP, admit quantum verifiers that only act on a constant number of qubits of a polynomial size quantum proof and have a constant gap between completeness and soundness. Despite an impressive body of work trying to prove or disprove the quantum PCP conjecture, it still remains widely open. The abovementioned proof verification statement has also been shown equivalent to the QMAcompleteness of the Local Hamiltonian problem with constant relative gap. Nevertheless, unlike in the classical case, no equivalent formulation in the language of multiprover games is known. In this work, we propose a new type of quantum proof systems, the Pointer QPCP, where a verifier first accesses a classical proof that he can use as a pointer to which qubits from the quantum part of the proof to access. We define the Pointer QPCP conjecture, that states that all problems in QMA admit quantum verifiers that first access a logarithmic number of bits from the classical part of a polynomial size proof, then act on a constant number of qubits from the quantum part of the proof, and have a constant gap between completeness and soundness. We define a new QMAcomplete problem, the Set Local Hamiltonian problem, and a new restricted class of quantum multiprover games, called CRESP games. We use them to provide two other equivalent statements to the Pointer QPCP conjecture: the Set Local Hamiltonian problem with constant relative gap is QMAcomplete; and the approximation of the maximum acceptance probability of CRESP games up to a constant additive factor is as hard as QMA. Our new conjecture is weaker than the original QPCP conjecture and hence provides a natural intermediate step towards proving the quantum PCP theorem. Furthermore, this is the first equivalence between a quantum PCP statement and the inapproximability of quantum multiprover games.
Item Type:  Book Section 

Subjects:  Q Science > QA Mathematics and Computer Science > QA75 Electronic computers. Computer science / számítástechnika, számítógéptudomány 
Divisions:  Informatics Laboratory 
SWORD Depositor:  MTMT Injector 
Depositing User:  MTMT Injector 
Date Deposited:  14 Mar 2019 07:22 
Last Modified:  21 Jul 2019 13:27 
URI:  https://eprints.sztaki.hu/id/eprint/9650 
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