English

Ensemble-based gradient inference for particle methods in optimization and sampling

Machine Learning 2023-03-02 v2 Machine Learning Statistics Theory Statistics Theory

Abstract

We propose an approach based on function evaluations and Bayesian inference to extract higher-order differential information of objective functions {from a given ensemble of particles}. Pointwise evaluation {V(xi)}i\{V(x^i)\}_i of some potential VV in an ensemble {xi}i\{x^i\}_i contains implicit information about first or higher order derivatives, which can be made explicit with little computational effort (ensemble-based gradient inference -- EGI). We suggest to use this information for the improvement of established ensemble-based numerical methods for optimization and sampling such as Consensus-based optimization and Langevin-based samplers. Numerical studies indicate that the augmented algorithms are often superior to their gradient-free variants, in particular the augmented methods help the ensembles to escape their initial domain, to explore multimodal, non-Gaussian settings and to speed up the collapse at the end of optimization dynamics.} The code for the numerical examples in this manuscript can be found in the paper's Github repository (https://github.com/MercuryBench/ensemble-based-gradient.git).

Keywords

Cite

@article{arxiv.2209.15420,
  title  = {Ensemble-based gradient inference for particle methods in optimization and sampling},
  author = {Claudia Schillings and Claudia Totzeck and Philipp Wacker},
  journal= {arXiv preprint arXiv:2209.15420},
  year   = {2023}
}
R2 v1 2026-06-28T02:27:13.555Z