Ensemble-Conditional Gaussian Processes (Ens-CGP): Representation, Geometry, and Inference
Abstract
We formulate Ensemble-Conditional Gaussian Processes (Ens-CGP), a finite-dimensional synthesis that centers ensemble-based inference on the conditional Gaussian law. Conditional Gaussian processes (CGP) arise directly from Gaussian processes under conditioning and, in linear-Gaussian settings, define the full posterior distribution for a Gaussian prior and linear observations. Classical Kalman filtering is a recursive algorithm that computes this same conditional law under dynamical assumptions; the conditional Gaussian law itself is therefore the underlying representational object, while the filter is one computational realization. In this sense, CGP provides the probabilistic foundation for Kalman-type methods as well as equivalent formulations as a strictly convex quadratic program (MAP estimation), RKHS-regularized regression, and classical regularization. Ens-CGP is the ensemble instantiation of this object, obtained by treating empirical ensemble moments as a (possibly low-rank) Gaussian prior and performing exact conditioning. By separating representation (GP -> CGP -> Ens-CGP) from computation (Kalman filters, EnKF variants, and iterative ensemble schemes), the framework links an earlier-established representational foundation for inference to ensemble-derived priors and clarifies the relationships among probabilistic, variational, and ensemble perspectives.
Keywords
Cite
@article{arxiv.2602.13871,
title = {Ensemble-Conditional Gaussian Processes (Ens-CGP): Representation, Geometry, and Inference},
author = {Sai Ravela and Jae Deok Kim and Kenneth Gee and Xingjian Yan and Samson Mercier and Lubna Albarghouty and Anamitra Saha},
journal= {arXiv preprint arXiv:2602.13871},
year = {2026}
}
Comments
20 pages. Technical manuscrupt on representational equivalence between conditional Gaussian inference, quadratic optimization, and RKHS geometry in finite dimensions