Testing noisy low-degree polynomials for sparsity
Abstract
We consider the problem of testing whether an unknown low-degree polynomial p over Rn is sparse versus far from sparse, given access to noisy evaluations of the polynomial p at randomly chosen points. This is a property-testing analogue of classical problems on learning sparse low-degree polynomials with noise, extending the work of Chen, De, and Servedio (2020) from noisy linear functions to general low-degree polynomials. Our main result gives a precise characterization of when sparsity testing for low-degree polynomials admits constant sample complexity independent of dimension, together with a matching constant-sample algorithm in that regime. For any mean-zero, variance-one finitely supported distribution X over the reals, degree d, and any sparsity parameters s ≤ T, we define a computable function MSGX,d(·), and: - For T MSGX,d(s), we give an Os,X,d(1)-sample algorithm that distinguishes whether a multilinear degree-d polynomial over Rn is s-sparse versus -far from T-sparse, given examples (x,\, p(x) + noise)x X n. Crucially, the sample complexity is completely independent of the ambient dimension n. - For T ≤ MSGX,d(s) - 1, we show that even without noise, any algorithm given samples (x,p(x))x X n must use X,d,s( n) examples. Our techniques employ a generalization of the results of Dinur et al. (2007) on the Fourier tails of bounded functions over \0,1\n to a broad range of finitely supported distributions, which may be of independent interest.
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