Non-Signaling Proofs with $O(\sqrt{\log n})$ Provers are in PSPACE

TL;DR

This paper demonstrates that non-signaling proofs with up to roughly the square root of log n provers are contained within PSPACE, advancing understanding of their computational power and introducing new reduction techniques.

Contribution

It establishes that k-prover no-signaling proofs for k=O(√log n) are in PSPACE, using novel reductions and the concept of sub-no-signaling strategies.

Findings

k-prover no-signaling proofs with k=O(√log n) are in PSPACE

Introduces a reduction from sub-no-signaling to no-signaling strategies

Provides space-efficient approximation methods for sub-no-signaling game values

Abstract

Non-signaling proofs, motivated by quantum computation, have found applications in cryptography and hardness of approximation. An important open problem is characterizing the power of no-signaling proofs. It is known that 2-prover no-signaling proofs are characterized by PSPACE, and that no-signaling proofs with $poly(n)$-provers are characterized by EXP. However, the power of $k$-prover no-signaling proofs, for $2<k<poly(n)$ remained an open problem. We show that $k$-prover no-signaling proofs (with negligible soundness) for $k=O(\sqrt{\log n})$ are contained in PSPACE. We prove this via two different routes that are of independent interest. In both routes we consider a relaxation of no-signaling called sub-no-signaling. Our main technical contribution (which is used in both our proofs) is a reduction showing how to convert any sub-no-signaling strategy with value at least $1-2^{-\Omega(k^2)}$ into a no-signaling one with value at least $2^{-O(k^2)}$. In the first route, we show that the classical prover reduction method for converting $k$-prover games into $2$-prover games carries over to the no-signaling setting with the following loss in soundness: if a $k$-player game has value less than $2^{-ck^2}$ (for some constant~$c>0$), then the corresponding 2-prover game has value at most $1 - 2^{dk^2}$ (for some constant~$d>0$). In the second route we show that the value of a sub-no-signaling game can be approximated in space that is polynomial in the communication complexity and exponential in the number of provers.