On relating one-way classical and quantum communication complexities

Abstract

Communication complexity is the amount of communication needed to compute a function when the function inputs are distributed over multiple parties. In its simplest form, one-way communication complexity, Alice and Bob compute a function f(x,y), where x is given to Alice and y is given to Bob, and only one message from Alice to Bob is allowed. A fundamental question in quantum information is the relationship between one-way quantum and classical communication complexities, i.e., how much shorter the message can be if Alice is sending a quantum state instead of bit strings? We make some progress towards this question with the following results. Let f: X × Y → Z \\ be a partial function and μ be a distribution with support contained in f-1(Z). Denote d=|Z|. Let R1,με(f) be the classical one-way communication complexity of f; Q1,με(f) be the quantum one-way communication complexity of f and Q1,μ, *ε(f) be the entanglement-assisted quantum one-way communication complexity of f, each with distributional error (average error over μ) at most ε. We show: 1) If μ is a product distribution, η > 0 and 0 ≤ ε ≤ 1-1/d, then, R1,μ2ε -dε2/(d-1)+ η(f) ≤ 2Q1,μ, *ε(f) + O( (1/η)). 2)If μ is a non-product distribution and Z=\ 0,1\, then ∀ ε, η > 0 such that ε/η + η < 0.5, R1,μ3η(f) = O(Q1,με(f) · CS(f)/η3), where \[CS(f) = y z∈\0,1\ \x~|~f(x,y)=z\ .\]