Information theoretic limits of robust sub-Gaussian mean estimation under star-shaped constraints

Abstract

We obtain the minimax rate for a mean location model with a bounded star-shaped set K ⊂eq Rn constraint on the mean, in an adversarially corrupted data setting with Gaussian noise. We assume an unknown fraction ε 1/2- for some fixed ∈(0,1/2] of N observations are arbitrarily corrupted. We obtain a minimax risk up to proportionality constants under the squared 2 loss of (η*2,σ2ε2) d2 with align* η* = \η 0 : Nη2σ2 ≤ MKloc(η,c)\, align* where MKloc(η,c) denotes the local entropy of the set K, d is the diameter of K, σ2 is the variance, and c is some sufficiently large absolute constant. A variant of our algorithm achieves the same rate for settings with known or symmetric sub-Gaussian noise, with a smaller breakdown point, still of constant order. We further study the case of unknown sub-Gaussian noise and show that the rate is slightly slower: (η*2,σ2ε2(1/ε)) d2. We generalize our results to the case when K is star-shaped but unbounded.

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