Breaking The Dimension Dependence in Sparse Distribution Estimation under Communication Constraints
Abstract
We consider the problem of estimating a d-dimensional s-sparse discrete distribution from its samples observed under a b-bit communication constraint. The best-known previous result on 2 estimation error for this problem is O( s( d/s)n2b). Surprisingly, we show that when sample size n exceeds a minimum threshold n*(s, d, b), we can achieve an 2 estimation error of O( sn2b). This implies that when n>n*(s, d, b) the convergence rate does not depend on the ambient dimension d and is the same as knowing the support of the distribution beforehand. We next ask the question: ``what is the minimum n*(s, d, b) that allows dimension-free convergence?''. To upper bound n*(s, d, b), we develop novel localization schemes to accurately and efficiently localize the unknown support. For the non-interactive setting, we show that n*(s, d, b) = O( ( d22 d/2b, s42 d/2b) ). Moreover, we connect the problem with non-adaptive group testing and obtain a polynomial-time estimation scheme when n = (s44 d/2b). This group testing based scheme is adaptive to the sparsity parameter s, and hence can be applied without knowing it. For the interactive setting, we propose a novel tree-based estimation scheme and show that the minimum sample-size needed to achieve dimension-free convergence can be further reduced to n*(s, d, b) = O( s22 d/2b ).
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