English

Practical Deep Heteroskedastic Regression

Machine Learning 2026-03-03 v1

Abstract

Uncertainty quantification (UQ) in deep learning regression is of wide interest, as it supports critical applications including sequential decision making and risk-sensitive tasks. In heteroskedastic regression, where the uncertainty of the target depends on the input, a common approach is to train a neural network that parameterizes the mean and the variance of the predictive distribution. Still, training deep heteroskedastic regression models poses practical challenges in the trade-off between uncertainty quantification and mean prediction, such as optimization difficulties, representation collapse, and variance overfitting. In this work we identify previously undiscussed fallacies and propose a simple and efficient procedure that addresses these challenges jointly by post-hoc fitting a variance model across the intermediate layers of a pretrained network on a hold-out dataset. We demonstrate that our method achieves on-par or state-of-the-art uncertainty quantification on several molecular graph datasets, without compromising mean prediction accuracy and remaining cheap to use at prediction time.

Keywords

Cite

@article{arxiv.2603.01750,
  title  = {Practical Deep Heteroskedastic Regression},
  author = {Mikkel Jordahn and Jonas Vestergaard Jensen and James Harrison and Michael Riis Andersen and Mikkel N. Schmidt},
  journal= {arXiv preprint arXiv:2603.01750},
  year   = {2026}
}
R2 v1 2026-07-01T10:59:01.622Z