Robust Simulation Based Inference Through Robust Optimal Transport

Abstract

When a statistical model \Pθ : θ∈ Θ\ lacks analytically tractable likelihoods, parametric statistical inference based on data generated from an unknown underlying distribution P can still be performed as long as simulations from the model are possible. This approach is called Simulation Based Inference (SBI). Statistical models are rarely exactly correct (that is, P \Pθ: θ∈ Θ\), and Robust SBI focuses on inferring a reasonable parameter even under model mis-specification. We focus on the setting where P possesses potentially both geometric and Total Variation type discrepancies from Pθ*. For this problem, we use a Kullback-Liebler informed robust Optimal Transport divergence, motivated by Empirical Likelihood considerations. We introduce a stochastic sub-gradient ascent algorithm with a convergence guarantee for estimating the semi-discrete version of this robust Optimal Transport divergence, and design a parallelized SBI algorithm which employs the regular bootstrap on top of minimum semi-discrete robust Optimal Transport for parameter uncertainty quantification. We demonstrate mathematically why the divergence is robust under a joint geometric plus Total Variation type contamination and then illustrate the robustness of inferences on a complex benchmark SBI task.