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Mean Estimation in High-Dimensional Binary Markov Gaussian Mixture Models

Statistics Theory 2022-10-13 v3 Information Theory Machine Learning math.IT Statistics Theory

Abstract

We consider a high-dimensional mean estimation problem over a binary hidden Markov model, which illuminates the interplay between memory in data, sample size, dimension, and signal strength in statistical inference. In this model, an estimator observes nn samples of a dd-dimensional parameter vector θRd\theta_{*}\in\mathbb{R}^{d}, multiplied by a random sign Si S_i (1in1\le i\le n), and corrupted by isotropic standard Gaussian noise. The sequence of signs {Si}i[n]{1,1}n\{S_{i}\}_{i\in[n]}\in\{-1,1\}^{n} is drawn from a stationary homogeneous Markov chain with flip probability δ[0,1/2]\delta\in[0,1/2]. As δ\delta varies, this model smoothly interpolates two well-studied models: the Gaussian Location Model for which δ=0\delta=0 and the Gaussian Mixture Model for which δ=1/2\delta=1/2. Assuming that the estimator knows δ\delta, we establish a nearly minimax optimal (up to logarithmic factors) estimation error rate, as a function of θ,δ,d,n\|\theta_{*}\|,\delta,d,n. We then provide an upper bound to the case of estimating δ\delta, assuming a (possibly inaccurate) knowledge of θ\theta_{*}. The bound is proved to be tight when θ\theta_{*} is an accurately known constant. These results are then combined to an algorithm which estimates θ\theta_{*} with δ\delta unknown a priori, and theoretical guarantees on its error are stated.

Keywords

Cite

@article{arxiv.2206.02455,
  title  = {Mean Estimation in High-Dimensional Binary Markov Gaussian Mixture Models},
  author = {Yihan Zhang and Nir Weinberger},
  journal= {arXiv preprint arXiv:2206.02455},
  year   = {2022}
}
R2 v1 2026-06-24T11:40:13.321Z