English

List Estimation

Information Theory 2026-03-27 v1 math.IT Statistics Theory Statistics Theory

Abstract

Classical estimation outputs a single point estimate of an unknown dd-dimensional vector from an observation. In this paper, we study \emph{kk-list estimation}, in which a single observation is used to produce a list of kk candidate estimates and performance is measured by the expected squared distance from the true vector to the closest candidate. We compare this centralized setting with a symmetric decentralized MMSE benchmark in which kk agents observe conditionally i.i.d.\ measurements and each agent outputs its own MMSE estimate. On the centralized side, we show that optimal kk-list estimation is equivalent to fixed-rate kk-point vector quantization of the posterior distribution and, under standard regularity conditions, admits an exact high-rate asymptotic expansion with explicit constants and decay rate k2/dk^{-2/d}. On the decentralized side, we derive lower bounds in terms of the small-ball behavior of the single-agent MMSE error; in particular, when the conditional error density is bounded near the origin, the benchmark distortion cannot decay faster than order k2/dk^{-2/d}. We further show that if the error density vanishes at the origin, then the decentralized benchmark is provably unable to match the centralized k2/dk^{-2/d} exponent, whereas the centralized estimator retains that scaling. Gaussian specializations yield explicit formulas and numerical experiments corroborate the predicted asymptotic behavior. Overall, the results show that, in the scaling with kk, one observation combined with kk carefully chosen candidates can be asymptotically as effective as -- and in some regimes strictly better than -- this MMSE-based decentralized benchmark with kk independent observations.

Keywords

Cite

@article{arxiv.2603.25280,
  title  = {List Estimation},
  author = {Nikola Zlatanov and Amin Gohari and Farzad Shahrivari and Mikhail Rudakov},
  journal= {arXiv preprint arXiv:2603.25280},
  year   = {2026}
}
R2 v1 2026-07-01T11:38:59.310Z