Flow-Induced Diagonal Gaussian Processes
DOI:
https://doi.org/10.1609/aaai.v40i28.39527Abstract
We present Flow-Induced Diagonal Gaussian Processes (FiD-GP), a compression framework that incorporates a compact inducing weight matrix to project a neural network’s weight uncertainty into a lower-dimensional subspace. Critically, FiD-GP relies on normalising flow variational posterior and spectral regularisations to augment its expressiveness and align the inducing subspace with feature-gradient geometry through a numerically stable projection mechanism objective. Furthermore, we demonstrate how the prediction framework in FiD-GP can help to design a single pass projection for Out-of-Distribution (OoD) detection. Our analysis shows that FiD-GP improves uncertainty estimation ability on various tasks compared with SVGP-based baselines, satisfies tight spectral residual bounds with theoretically guaranteed OoD detection, and significantly compresses the neural network’s storage requirements at the cost of increased inference computation dependent on the number of inducing weights employed. Specifically, in a comprehensive empirical study spanning regression, image classification, semantic segmentation, and Out-of-Distribution detection benchmarks, it significantly cuts Bayesian training cost, compresses parameters by roughly 51%, reduces model size by about 75%, and matches state-of-the-art accuracy and uncertainty estimation.
Published
2026-03-14
How to Cite
Lin, M., Patane, A., Jing, W., Guan, S., & Botterweck, G. (2026). Flow-Induced Diagonal Gaussian Processes. Proceedings of the AAAI Conference on Artificial Intelligence, 40(28), 23550–23558. https://doi.org/10.1609/aaai.v40i28.39527
Issue
Section
AAAI Technical Track on Machine Learning V
