Moments, Random Walks, and Limits for Spectrum Approximation
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We study lower bounds for the problem of approximating a one dimensional distribution given (noisy) measurements of its moments. We show that there are distributions on [-1,1] that cannot be approximated to accuracy ϵ in Wasserstein-1 distance even if we know all of their moments to multiplicative accuracy (1±2^-Ω(1/ϵ)); this result matches an upper bound of Kong and Valiant [Annals of Statistics, 2017]. To obtain our result, we provide a hard instance involving distributions induced by the eigenvalue spectra of carefully constructed graph adjacency matrices. Efficiently approximating such spectra in Wasserstein-1 distance is a well-studied algorithmic problem, and a recent result of Cohen-Steiner et al. [KDD 2018] gives a method based on accurately approximating spectral moments using 2^O(1/ϵ) random walks initiated at uniformly random nodes in the graph. As a strengthening of our main result, we show that improving the dependence on 1/ϵ in this result would require a new algorithmic approach. Specifically, no algorithm can compute an ϵ-accurate approximation to the spectrum of a normalized graph adjacency matrix with constant probability, even when given the transcript of 2^Ω(1/ϵ) random walks of length 2^Ω(1/ϵ) started at random nodes.
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