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Pointwise Bounds for Distribution Estimation under Communication Constraints

Information Theory 2021-11-02 v2 math.IT

Abstract

We consider the problem of estimating a dd-dimensional discrete distribution from its samples observed under a bb-bit communication constraint. In contrast to most previous results that largely focus on the global minimax error, we study the local behavior of the estimation error and provide \emph{pointwise} bounds that depend on the target distribution pp. In particular, we show that the 2\ell_2 error decays with O(p1/2n2b1n)O\left(\frac{\lVert p\rVert_{1/2}}{n2^b}\vee \frac{1}{n}\right) (In this paper, we use aba\vee b and aba \wedge b to denote max(a,b)\max(a, b) and min(a,b)\min(a,b) respectively.) when nn is sufficiently large, hence it is governed by the \emph{half-norm} of pp instead of the ambient dimension dd. For the achievability result, we propose a two-round sequentially interactive estimation scheme that achieves this error rate uniformly over all pp. Our scheme is based on a novel local refinement idea, where we first use a standard global minimax scheme to localize pp and then use the remaining samples to locally refine our estimate. We also develop a new local minimax lower bound with (almost) matching 2\ell_2 error, showing that any interactive scheme must admit a Ω(p(1+δ)/2n2b)\Omega\left( \frac{\lVert p \rVert_{{(1+\delta)}/{2}}}{n2^b}\right) 2\ell_2 error for any δ>0\delta > 0. The lower bound is derived by first finding the best parametric sub-model containing pp, and then upper bounding the quantized Fisher information under this model. Our upper and lower bounds together indicate that the H1/2(p)=log(p1/2)\mathcal{H}_{1/2}(p) = \log(\lVert p \rVert_{{1}/{2}}) bits of communication is both sufficient and necessary to achieve the optimal (centralized) performance, where H1/2(p)\mathcal{H}_{{1}/{2}}(p) is the R\'enyi entropy of order 22. Therefore, under the 2\ell_2 loss, the correct measure of the local communication complexity at pp is its R\'enyi entropy.

Keywords

Cite

@article{arxiv.2110.03189,
  title  = {Pointwise Bounds for Distribution Estimation under Communication Constraints},
  author = {Wei-Ning Chen and Peter Kairouz and Ayfer Özgür},
  journal= {arXiv preprint arXiv:2110.03189},
  year   = {2021}
}
R2 v1 2026-06-24T06:41:32.103Z