Entangled Mean Estimation in High-Dimensions
January 09, 2025 Β· Declared Dead Β· π Symposium on the Theory of Computing
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Authors
Ilias Diakonikolas, Daniel M. Kane, Sihan Liu, Thanasis Pittas
arXiv ID
2501.05425
Category
cs.DS: Data Structures & Algorithms
Cross-listed
cs.LG,
math.ST,
stat.ML
Citations
1
Venue
Symposium on the Theory of Computing
Last Checked
4 months ago
Abstract
We study the task of high-dimensional entangled mean estimation in the subset-of-signals model. Specifically, given $N$ independent random points $x_1,\ldots,x_N$ in $\mathbb{R}^D$ and a parameter $Ξ±\in (0, 1)$ such that each $x_i$ is drawn from a Gaussian with mean $ΞΌ$ and unknown covariance, and an unknown $Ξ±$-fraction of the points have identity-bounded covariances, the goal is to estimate the common mean $ΞΌ$. The one-dimensional version of this task has received significant attention in theoretical computer science and statistics over the past decades. Recent work [LY20; CV24] has given near-optimal upper and lower bounds for the one-dimensional setting. On the other hand, our understanding of even the information-theoretic aspects of the multivariate setting has remained limited. In this work, we design a computationally efficient algorithm achieving an information-theoretically near-optimal error. Specifically, we show that the optimal error (up to polylogarithmic factors) is $f(Ξ±,N) + \sqrt{D/(Ξ±N)}$, where the term $f(Ξ±,N)$ is the error of the one-dimensional problem and the second term is the sub-Gaussian error rate. Our algorithmic approach employs an iterative refinement strategy, whereby we progressively learn more accurate approximations $\hat ΞΌ$ to $ΞΌ$. This is achieved via a novel rejection sampling procedure that removes points significantly deviating from $\hat ΞΌ$, as an attempt to filter out unusually noisy samples. A complication that arises is that rejection sampling introduces bias in the distribution of the remaining points. To address this issue, we perform a careful analysis of the bias, develop an iterative dimension-reduction strategy, and employ a novel subroutine inspired by list-decodable learning that leverages the one-dimensional result.
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