Open Access
2023 Discrepancy-based inference for intractable generative models using Quasi-Monte Carlo
Ziang Niu, Johanna Meier, François-Xavier Briol
Author Affiliations +
Electron. J. Statist. 17(1): 1411-1456 (2023). DOI: 10.1214/23-EJS2131

Abstract

Intractable generative models, or simulators, are models for which the likelihood is unavailable but sampling is possible. Most approaches to parameter inference in this setting require the computation of some discrepancy between the data and the generative model. This is for example the case for minimum distance estimation and approximate Bayesian computation. These approaches require simulating a high number of realisations from the model for different parameter values, which can be a significant challenge when simulating is an expensive operation. In this paper, we propose to enhance this approach by enforcing “sample diversity” in simulations of our models. This will be implemented through the use of quasi-Monte Carlo (QMC) point sets. Our key results are sample complexity bounds which demonstrate that, under smoothness conditions on the generator, QMC can significantly reduce the number of samples required to obtain a given level of accuracy when using three of the most common discrepancies: the maximum mean discrepancy, the Wasserstein distance, and the Sinkhorn divergence. This is complemented by a simulation study which highlights that an improved accuracy is sometimes also possible in some settings which are not covered by the theory.

Funding Statement

FXB was supported by the Lloyd’s Register Foundation programme on data-centric engineering at The Alan Turing Institute under the EPSRC grant [EP/N510129/1].

Acknowledgments

The authors are grateful to Chris Oates and four anonymous reviewers for helpful comments and suggestions on this paper.

Citation

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Ziang Niu. Johanna Meier. François-Xavier Briol. "Discrepancy-based inference for intractable generative models using Quasi-Monte Carlo." Electron. J. Statist. 17 (1) 1411 - 1456, 2023. https://doi.org/10.1214/23-EJS2131

Information

Received: 1 July 2022; Published: 2023
First available in Project Euclid: 5 May 2023

arXiv: 2106.11561
MathSciNet: MR4584870
zbMATH: 07690327
Digital Object Identifier: 10.1214/23-EJS2131

Subjects:
Primary: 60K35 , 60K35
Secondary: 60K35

Keywords: Approximate Bayesian Computation , Discrepancy , generative models , intractable models inference , minimum distance estimation , quasi-Monte Carlo , sample complexity

Vol.17 • No. 1 • 2023
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