Likelihood-free hypothesis testing

Abstract

Consider the problem of binary hypothesis testing. Given Z coming from either P m or Q m, to decide between the two with small probability of error it is sufficient, and in many cases necessary, to have m1/ε2, where ε measures the separation between P and Q in total variation (TV). Achieving this, however, requires complete knowledge of the distributions and can be done, for example, using the Neyman-Pearson test. In this paper we consider a variation of the problem which we call likelihood-free hypothesis testing, where access to P and Q is given through n i.i.d. observations from each. In the case when P and Q are assumed to belong to a non-parametric family, we demonstrate the existence of a fundamental trade-off between n and m given by nm nGoF2(ε), where nGoF(ε) is the minimax sample complexity of testing between the hypotheses H0:\, P= Q vs H1:\, TV( P, Q)≥ε. We show this for three families of distributions, in addition to the family of all discrete distributions for which we obtain a more complicated trade-off exhibiting an additional phase-transition. Our results demonstrate the possibility of testing without fully estimating P and Q, provided m 1/ε2.

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