Quantum advantage in zero-error function computation with side information

Abstract

We consider the problem of zero-error function computation with side information. Alice and Bob have correlated sources X,Y with joint p.m.f. pXY(·, ·). Bob wants to calculate f(X,Y) with zero error. Alice encodes m-length blocks (m ≥ 1) of her observations to Bob over error-free channels, which can be classical or quantum. We consider two classical settings. (i) Alice communicates via a fixed length code (FLC), and (ii) Alice communicates via a variable length code (VLC). In the FLC scenario, the minimum communication rate depends on the asymptotic growth of the chromatic number of an appropriately defined m-instance ``confusion graph'' G(m). In the VLC scenario, the corresponding rate is characterized by the asymptotics of the chromatic entropy of G(m). %and has single-letter characterization in terms of K\"orner's graph entropy if G(m) is m-times graph OR product. In the quantum setting, we only consider fixed length codes; the corresponding rate depends on the asymptotic growth of the orthogonal rank of the complement of G(m). The behavior of the communication rates depends critically on G(m), which is shown to be sandwiched between G m (m-times strong product) and G m (m-times OR product) respectively. Our work presents necessary and sufficient conditions on the function f(·, ·) and joint p.m.f. pXY(·,·) such that G(m) equals either G m or G m. Our work explores the multitude of possible behaviors of the quantum and classical (FLC/VLC) rates in the single-instance case and the asymptotic (in m) case for several classes of confusion graphs.