New one shot quantum protocols with application to communication complexity

Abstract

In this paper we present the following quantum compression protocol: P : Let ,σ be quantum states such that S( || σ) = Tr ( - σ), the relative entropy between and σ, is finite. Alice gets to know the eigen-decomposition of . Bob gets to know the eigen-decomposition of σ. Both Alice and Bob know S( || σ) and an error parameter ε. Alice and Bob use shared entanglement and after communication of O((S( || σ)+1)/ε4) bits from Alice to Bob, Bob ends up with a quantum state such that F(, ) ≥ 1 - 5ε, where F(·) represents fidelity. This result can be considered as a non-commutative generalization of a result due to Braverman and Rao [2011] where they considered the special case when and σ are classical probability distributions (or commute with each other) and use shared randomness instead of shared entanglement. We use P to obtain an alternate proof of a direct-sum result for entanglement assisted quantum one-way communication complexity for all relations, which was first shown by Jain, Radhakrishnan and Sen [2005,2008]. We also present a variant of protocol P in which Bob has some side information about the state with Alice. We show that in such a case, the amount of communication can be further reduced, based on the side information that Bob has. Our second result provides a quantum analogue of the widely used classical correlated-sampling protocol. For example, Holenstein [2007] used the classical correlated-sampling protocol in his proof of a parallel-repetition theorem for two-player one-round games.