Parameter estimation with data-driven nonparametric likelihood functions

TL;DR

This paper introduces a data-driven nonparametric likelihood estimation method using spectral expansion and diffusion maps, improving parameter inference robustness especially on low-dimensional, unknown, or non-smooth data manifolds.

Contribution

It develops a novel likelihood estimation approach that respects data geometry and provides error bounds independent of basis function variance, outperforming traditional methods.

Findings

Robustness demonstrated on stochastic and deterministic differential equations.

Superior performance on low-dimensional, unknown, or non-smooth data manifolds.

Error bounds are independent of basis function variance.

Abstract

In this paper, we consider a surrogate modeling approach using a data-driven nonparametric likelihood function constructed on a manifold on which the data lie (or to which they are close). The proposed method represents the likelihood function using a spectral expansion formulation known as the kernel embedding of the conditional distribution. To respect the geometry of the data, we employ this spectral expansion using a set of data-driven basis functions obtained from the diffusion maps algorithm. The theoretical error estimate suggests that the error bound of the approximate data-driven likelihood function is independent of the variance of the basis functions, which allows us to determine the amount of training data for accurate likelihood function estimations. Supporting numerical results to demonstrate the robustness of the data-driven likelihood functions for parameter estimation are given on instructive examples involving stochastic and deterministic differential equations. When the dimension of the data manifold is strictly less than the dimension of the ambient space, we found that the proposed approach (which does not require the knowledge of the data manifold) is superior compared to likelihood functions constructed using standard parametric basis functions defined on the ambient coordinates. In an example where the data manifold is not smooth and unknown, the proposed method is more robust compared to an existing polynomial chaos surrogate model which assumes a parametric likelihood, the non-intrusive spectral projection.