Non-iid hypothesis testing: from classical to quantum

Abstract

We study hypothesis testing (aka state certification) in the non-identically distributed setting. A recent work (Garg et al. 2023) considered the classical case, in which one is given (independent) samples from T unknown probability distributions p1, …, pT on [d] = \1, 2, …, d\, and one wishes to accept/reject the hypothesis that their average pavg equals a known hypothesis distribution q. Garg et al. showed that if one has just c = 2 samples from each pi, and provided T dε2 + 1ε4, one can (whp) distinguish pavg = q from dTV(pavg,q) > ε. This nearly matches the optimal result for the classical iid setting (namely, T dε2). Besides optimally improving this result (and generalizing to tolerant testing with more stringent distance measures), we study the analogous problem of hypothesis testing for non-identical quantum states. Here we uncover an unexpected phenomenon: for any d-dimensional hypothesis state σ, and given just a single copy (c = 1) of each state 1, …, T, one can distinguish avg = σ from Dtr(avg,σ) > ε provided T d/ε2. (Again, we generalize to tolerant testing with more stringent distance measures.) This matches the optimal result for the iid case, which is surprising because doing this with c = 1 is provably impossible in the classical case. We also show that the analogous phenomenon happens for the non-iid extension of identity testing between unknown states. A technical tool we introduce may be of independent interest: an Efron-Stein inequality, and more generally an Efron-Stein decomposition, in the quantum setting.

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