Discriminating quantum states: the multiple Chernoff distance

Abstract

We consider the problem of testing multiple quantum hypotheses \1 n,…,r n\, where an arbitrary prior distribution is given and each of the r hypotheses is n copies of a quantum state. It is known that the average error probability Pe decays exponentially to zero, that is, Pe=\- n+o(n)\. However, this error exponent is generally unknown, except for the case that r=2. In this paper, we solve the long-standing open problem of identifying the above error exponent, by proving Nussbaum and Szko a's conjecture that =i≠ jC(i,j). The right-hand side of this equality is called the multiple quantum Chernoff distance, and C(i,j):=0≤ s≤ 1\-Trisj1-s\ has been previously identified as the optimal error exponent for testing two hypotheses, i n versus j n. The main ingredient of our proof is a new upper bound for the average error probability, for testing an ensemble of finite-dimensional, but otherwise general, quantum states. This upper bound, up to a states-dependent factor, matches the multiple-state generalization of Nussbaum and Szko a's lower bound. Specialized to the case r=2, we give an alternative proof to the achievability of the binary-hypothesis Chernoff distance, which was originally proved by Audenaert et al.