Dimension-free estimators of gradients of functions with(out) non-independent variables

Abstract

This study proposes a unified stochastic framework for approximating and computing the gradient of every smooth function evaluated at non-independent variables, using p-spherical distributions on d with d, p≥ 1. The upper-bounds of the bias of the gradient surrogates do not suffer from the curse of dimensionality for any p≥ 1. Also, the mean squared errors (MSEs) of the gradient estimators are bounded by K0 N-1 d for any p ∈ [1, 2], and by K1 N-1 d2/p when 2 ≤ p d with N the sample size and K0, K1 some constants. Taking \2, (d) \ < p d allows for achieving dimension-free upper-bounds of MSEs. In the case where d p< +∞, the upper-bound K2 N-1 d2-2/p/ (d+2)2 is reached with K2 a constant. Such results lead to dimension-free MSEs of the proposed estimators, which boil down to estimators of the traditional gradient when the variables are independent. Numerical comparisons show the efficiency of the proposed approach.

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