GGMPs: Generalized Gaussian Mixture Processes
Abstract
Conditional density estimation is complicated by multimodality, heteroscedasticity, and strong non-Gaussianity. Gaussian processes (GPs) provide a principled nonparametric framework with calibrated uncertainty, but standard GP regression is limited by its unimodal Gaussian predictive form. We introduce the Generalized Gaussian Mixture Process (GGMP), a GP-based method for multimodal conditional density estimation in settings where each input may be associated with a complex output distribution rather than a single scalar response. GGMP combines local Gaussian mixture fitting, cross-input component alignment and per-component heteroscedastic GP training to produce a closed-form Gaussian mixture predictive density. The method is tractable, compatible with standard GP solvers and scalable methods, and avoids the exponentially large latent-assignment structure of naive multimodal GP formulations. Empirically, GGMPs improve distributional approximation on synthetic and real-world datasets with pronounced non-Gaussianity and multimodality.
Keywords
Cite
@article{arxiv.2603.10442,
title = {GGMPs: Generalized Gaussian Mixture Processes},
author = {Vardaan Tekriwal and Mark D. Risser and Hengrui Luo and Marcus M. Noack},
journal= {arXiv preprint arXiv:2603.10442},
year = {2026}
}