Generalizing Stochastic Smoothing for Differentiation and Gradient Estimation
Abstract
We deal with the problem of gradient estimation for stochastic differentiable relaxations of algorithms, operators, simulators, and other non-differentiable functions. Stochastic smoothing conventionally perturbs the input of a non-differentiable function with a differentiable density distribution with full support, smoothing it and enabling gradient estimation. Our theory starts at first principles to derive stochastic smoothing with reduced assumptions, without requiring a differentiable density nor full support, and we present a general framework for relaxation and gradient estimation of non-differentiable black-box functions . We develop variance reduction for gradient estimation from 3 orthogonal perspectives. Empirically, we benchmark 6 distributions and up to 24 variance reduction strategies for differentiable sorting and ranking, differentiable shortest-paths on graphs, differentiable rendering for pose estimation, as well as differentiable cryo-ET simulations.
Cite
@article{arxiv.2410.08125,
title = {Generalizing Stochastic Smoothing for Differentiation and Gradient Estimation},
author = {Felix Petersen and Christian Borgelt and Aashwin Mishra and Stefano Ermon},
journal= {arXiv preprint arXiv:2410.08125},
year = {2024}
}