Mean-Field Nonparametric Estimation of Interacting Particle Systems
Abstract
This paper concerns the nonparametric estimation problem of the distribution-state dependent drift vector field in an interacting $N$-particle system. Observing single-trajectory data for each particle, we derive the mean-field rate of convergence for the maximum likelihood estimator (MLE), which depends on both Gaussian complexity and Rademacher complexity of the function class. In particular, when the function class contains $\alpha$-smooth H{ö}lder functions, our rate of convergence is minimax optimal on the order of $N^{-\frac{\alpha}{d+2\alpha}}$. Combining with a Fourier analytical deconvolution estimator, we derive the consistency of MLE for the external force and interaction kernel in the McKean-Vlasov equation.
Cite
Text
Yao et al. "Mean-Field Nonparametric Estimation of Interacting Particle Systems." Conference on Learning Theory, 2022.Markdown
[Yao et al. "Mean-Field Nonparametric Estimation of Interacting Particle Systems." Conference on Learning Theory, 2022.](https://mlanthology.org/colt/2022/yao2022colt-meanfield/)BibTeX
@inproceedings{yao2022colt-meanfield,
title = {{Mean-Field Nonparametric Estimation of Interacting Particle Systems}},
author = {Yao, Rentian and Chen, Xiaohui and Yang, Yun},
booktitle = {Conference on Learning Theory},
year = {2022},
pages = {2242-2275},
volume = {178},
url = {https://mlanthology.org/colt/2022/yao2022colt-meanfield/}
}