English

Cluster-Seeking James-Stein Estimators

Information Theory 2018-03-19 v4 math.IT Statistics Theory Machine Learning Statistics Theory

Abstract

This paper considers the problem of estimating a high-dimensional vector of parameters θRn\boldsymbol{\theta} \in \mathbb{R}^n from a noisy observation. The noise vector is i.i.d. Gaussian with known variance. For a squared-error loss function, the James-Stein (JS) estimator is known to dominate the simple maximum-likelihood (ML) estimator when the dimension nn exceeds two. The JS-estimator shrinks the observed vector towards the origin, and the risk reduction over the ML-estimator is greatest for θ\boldsymbol{\theta} that lie close to the origin. JS-estimators can be generalized to shrink the data towards any target subspace. Such estimators also dominate the ML-estimator, but the risk reduction is significant only when θ\boldsymbol{\theta} lies close to the subspace. This leads to the question: in the absence of prior information about θ\boldsymbol{\theta}, how do we design estimators that give significant risk reduction over the ML-estimator for a wide range of θ\boldsymbol{\theta}? In this paper, we propose shrinkage estimators that attempt to infer the structure of θ\boldsymbol{\theta} from the observed data in order to construct a good attracting subspace. In particular, the components of the observed vector are separated into clusters, and the elements in each cluster shrunk towards a common attractor. The number of clusters and the attractor for each cluster are determined from the observed vector. We provide concentration results for the squared-error loss and convergence results for the risk of the proposed estimators. The results show that the estimators give significant risk reduction over the ML-estimator for a wide range of θ\boldsymbol{\theta}, particularly for large nn. Simulation results are provided to support the theoretical claims.

Keywords

Cite

@article{arxiv.1602.00542,
  title  = {Cluster-Seeking James-Stein Estimators},
  author = {K. Pavan Srinath and Ramji Venkataramanan},
  journal= {arXiv preprint arXiv:1602.00542},
  year   = {2018}
}

Comments

Appeared in IEEE Transactions on Information Theory

R2 v1 2026-06-22T12:40:58.241Z