English

The square root rule for adaptive importance sampling

Statistics Theory 2019-04-01 v2 Computation Statistics Theory

Abstract

In adaptive importance sampling, and other contexts, we have K>1K>1 unbiased and uncorrelated estimates μ^k\hat\mu_k of a common quantity μ\mu. The optimal unbiased linear combination weights them inversely to their variances but those weights are unknown and hard to estimate. A simple deterministic square root rule based on a working model that Var(μ^k)k1/2\mathrm{Var}(\hat\mu_k)\propto k^{-1/2} gives an unbisaed estimate of μ\mu that is nearly optimal under a wide range of alternative variance patterns. We show that if Var(μ^k)ky\mathrm{Var}(\hat\mu_k)\propto k^{-y} for an unknown rate parameter y[0,1]y\in [0,1] then the square root rule yields the optimal variance rate with a constant that is too large by at most 9/89/8 for any 0y10\le y\le 1 and any number KK of estimates. Numerical work shows that rule is similarly robust to some other patterns with mildly decreasing variance as kk increases.

Keywords

Cite

@article{arxiv.1901.02976,
  title  = {The square root rule for adaptive importance sampling},
  author = {Art B. Owen and Yi Zhou},
  journal= {arXiv preprint arXiv:1901.02976},
  year   = {2019}
}
R2 v1 2026-06-23T07:07:38.122Z