English

On the complexity of zero gap MIP*

Quantum Physics 2020-04-30 v2 Computational Complexity

Abstract

The class MIP\mathsf{MIP}^* is the set of languages decidable by multiprover interactive proofs with quantum entangled provers. It was recently shown by Ji, Natarajan, Vidick, Wright and Yuen that MIP\mathsf{MIP}^* is equal to RE\mathsf{RE}, the set of recursively enumerable languages. In particular this shows that the complexity of approximating the quantum value of a non-local game GG is equivalent to the complexity of the Halting problem. In this paper we investigate the complexity of deciding whether the quantum value of a non-local game GG is exactly 11. This problem corresponds to a complexity class that we call zero gap MIP\mathsf{MIP}^*, denoted by MIP0\mathsf{MIP}^*_0, where there is no promise gap between the verifier's acceptance probabilities in the YES and NO cases. We prove that MIP0\mathsf{MIP}^*_0 extends beyond the first level of the arithmetical hierarchy (which includes RE\mathsf{RE} and its complement coRE\mathsf{coRE}), and in fact is equal to Π20\Pi_2^0, the class of languages that can be decided by quantified formulas of the form yzR(x,y,z)\forall y \, \exists z \, R(x,y,z). Combined with the previously known result that MIP0co\mathsf{MIP}^{co}_0 (the commuting operator variant of MIP0\mathsf{MIP}^*_0) is equal to coRE\mathsf{coRE}, our result further highlights the fascinating connection between various models of quantum multiprover interactive proofs and different classes in computability theory.

Cite

@article{arxiv.2002.10490,
  title  = {On the complexity of zero gap MIP*},
  author = {Hamoon Mousavi and Seyed Sajjad Nezhadi and Henry Yuen},
  journal= {arXiv preprint arXiv:2002.10490},
  year   = {2020}
}

Comments

Fixed typos and edited protocol to more smoothly follow from references

R2 v1 2026-06-23T13:52:13.360Z