Near-Optimal Mean Estimation with Unknown, Heteroskedastic Variances

December 05, 2023 Β· Declared Dead Β· πŸ› Symposium on the Theory of Computing

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Authors Spencer Compton, Gregory Valiant arXiv ID 2312.02417 Category math.ST Cross-listed cs.DS, stat.ML Citations 3 Venue Symposium on the Theory of Computing Last Checked 4 months ago
Abstract
Given data drawn from a collection of Gaussian variables with a common mean but different and unknown variances, what is the best algorithm for estimating their common mean? We present an intuitive and efficient algorithm for this task. As different closed-form guarantees can be hard to compare, the Subset-of-Signals model serves as a benchmark for heteroskedastic mean estimation: given $n$ Gaussian variables with an unknown subset of $m$ variables having variance bounded by 1, what is the optimal estimation error as a function of $n$ and $m$? Our algorithm resolves this open question up to logarithmic factors, improving upon the previous best known estimation error by polynomial factors when $m = n^c$ for all $0<c<1$. Of particular note, we obtain error $o(1)$ with $m = \tilde{O}(n^{1/4})$ variance-bounded samples, whereas previous work required $m = \tildeΞ©(n^{1/2})$. Finally, we show that in the multi-dimensional setting, even for $d=2$, our techniques enable rates comparable to knowing the variance of each sample.
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