Saved in:
Bibliographic Details
Main Authors: Yang, Yang, Ji, Chunlin, Li, Haoyang, Deng, Ke
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.27672
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866915897536413696
author Yang, Yang
Ji, Chunlin
Li, Haoyang
Deng, Ke
author_facet Yang, Yang
Ji, Chunlin
Li, Haoyang
Deng, Ke
contents Quantifying predictive uncertainty is essential for real world machine learning applications, especially in scenarios requiring reliable and interpretable predictions. Many common parametric approaches rely on neural networks to estimate distribution parameters by optimizing the negative log likelihood. However, these methods often encounter challenges like training instability and mode collapse, leading to poor estimates of the mean and variance of the target output distribution. In this work, we propose the Neural Energy Gaussian Mixture Model (NE-GMM), a novel framework that integrates Gaussian Mixture Model (GMM) with Energy Score (ES) to enhance predictive uncertainty quantification. NE-GMM leverages the flexibility of GMM to capture complex multimodal distributions and leverages the robustness of ES to ensure well calibrated predictions in diverse scenarios. We theoretically prove that the hybrid loss function satisfies the properties of a strictly proper scoring rule, ensuring alignment with the true data distribution, and establish generalization error bounds, demonstrating that the model's empirical performance closely aligns with its expected performance on unseen data. Extensive experiments on both synthetic and real world datasets demonstrate the superiority of NE-GMM in terms of both predictive accuracy and uncertainty quantification.
format Preprint
id arxiv_https___arxiv_org_abs_2603_27672
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Energy Score-Guided Neural Gaussian Mixture Model for Predictive Uncertainty Quantification
Yang, Yang
Ji, Chunlin
Li, Haoyang
Deng, Ke
Machine Learning
Quantifying predictive uncertainty is essential for real world machine learning applications, especially in scenarios requiring reliable and interpretable predictions. Many common parametric approaches rely on neural networks to estimate distribution parameters by optimizing the negative log likelihood. However, these methods often encounter challenges like training instability and mode collapse, leading to poor estimates of the mean and variance of the target output distribution. In this work, we propose the Neural Energy Gaussian Mixture Model (NE-GMM), a novel framework that integrates Gaussian Mixture Model (GMM) with Energy Score (ES) to enhance predictive uncertainty quantification. NE-GMM leverages the flexibility of GMM to capture complex multimodal distributions and leverages the robustness of ES to ensure well calibrated predictions in diverse scenarios. We theoretically prove that the hybrid loss function satisfies the properties of a strictly proper scoring rule, ensuring alignment with the true data distribution, and establish generalization error bounds, demonstrating that the model's empirical performance closely aligns with its expected performance on unseen data. Extensive experiments on both synthetic and real world datasets demonstrate the superiority of NE-GMM in terms of both predictive accuracy and uncertainty quantification.
title Energy Score-Guided Neural Gaussian Mixture Model for Predictive Uncertainty Quantification
topic Machine Learning
url https://arxiv.org/abs/2603.27672