The Price of Tolerance in Distribution Testing
Abstract
We revisit the problem of tolerant distribution testing. That is, given samples from an unknown distribution p over \1, …, n\, is it 1-close to or 2-far from a reference distribution q (in total variation distance)? Despite significant interest over the past decade, this problem is well understood only in the extreme cases. In the noiseless setting (i.e., 1 = 0) the sample complexity is (n), strongly sublinear in the domain size. At the other end of the spectrum, when 1 = 2/2, the sample complexity jumps to the barely sublinear (n/ n). However, very little is known about the intermediate regime. We fully characterize the price of tolerance in distribution testing as a function of n, 1, 2, up to a single n factor. Specifically, we show the sample complexity to be \[ (n22 + n n · \122,(122)\!\!2\),\] providing a smooth tradeoff between the two previously known cases. We also provide a similar characterization for the problem of tolerant equivalence testing, where both p and q are unknown. Surprisingly, in both cases, the main quantity dictating the sample complexity is the ratio 1/22, and not the more intuitive 1/2. Of particular technical interest is our lower bound framework, which involves novel approximation-theoretic tools required to handle the asymmetry between 1 and 2, a challenge absent from previous works.
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