English

Communication Complexity of Estimating Correlations

Information Theory 2019-04-19 v2 Machine Learning math.IT Statistics Theory Machine Learning Statistics Theory

Abstract

We characterize the communication complexity of the following distributed estimation problem. Alice and Bob observe infinitely many iid copies of ρ\rho-correlated unit-variance (Gaussian or ±1\pm1 binary) random variables, with unknown ρ[1,1]\rho\in[-1,1]. By interactively exchanging kk bits, Bob wants to produce an estimate ρ^\hat\rho of ρ\rho. We show that the best possible performance (optimized over interaction protocol Π\Pi and estimator ρ^\hat \rho) satisfies infΠρ^supρE[ρρ^2]=1k(12ln2+o(1))\inf_{\Pi \hat\rho}\sup_\rho \mathbb{E} [|\rho-\hat\rho|^2] = \tfrac{1}{k} (\frac{1}{2 \ln 2} + o(1)). Curiously, the number of samples in our achievability scheme is exponential in kk; by contrast, a naive scheme exchanging kk samples achieves the same Ω(1/k)\Omega(1/k) rate but with a suboptimal prefactor. Our protocol achieving optimal performance is one-way (non-interactive). We also prove the Ω(1/k)\Omega(1/k) bound even when ρ\rho is restricted to any small open sub-interval of [1,1][-1,1] (i.e. a local minimax lower bound). Our proof techniques rely on symmetric strong data-processing inequalities and various tensorization techniques from information-theoretic interactive common-randomness extraction. Our results also imply an Ω(n)\Omega(n) lower bound on the information complexity of the Gap-Hamming problem, for which we show a direct information-theoretic proof.

Keywords

Cite

@article{arxiv.1901.09100,
  title  = {Communication Complexity of Estimating Correlations},
  author = {Uri Hadar and Jingbo Liu and Yury Polyanskiy and Ofer Shayevitz},
  journal= {arXiv preprint arXiv:1901.09100},
  year   = {2019}
}
R2 v1 2026-06-23T07:22:43.527Z