Learning the Stein Discrepancy for Training and Evaluating Energy-Based Models without Sampling
Abstract
We present a new method for evaluating and training unnormalized density models. Our approach only requires access to the gradient of the unnormalized model's log-density. We estimate the Stein discrepancy between the data density and the model density defined by a vector function of the data. We parameterize this function with a neural network and fit its parameters to maximize the discrepancy. This yields a novel goodness-of-fit test which outperforms existing methods on high dimensional data. Furthermore, optimizing to minimize this discrepancy produces a novel method for training unnormalized models which scales more gracefully than existing methods. The ability to both learn and compare models is a unique feature of the proposed method.
Cite
@article{arxiv.2002.05616,
title = {Learning the Stein Discrepancy for Training and Evaluating Energy-Based Models without Sampling},
author = {Will Grathwohl and Kuan-Chieh Wang and Jorn-Henrik Jacobsen and David Duvenaud and Richard Zemel},
journal= {arXiv preprint arXiv:2002.05616},
year = {2020}
}
Comments
ICML 2020