Beyond Pinball Loss: Quantile Methods for Calibrated Uncertainty Quantification
Abstract
Among the many ways of quantifying uncertainty in a regression setting, specifying the full quantile function is attractive, as quantiles are amenable to interpretation and evaluation. A model that predicts the true conditional quantiles for each input, at all quantile levels, presents a correct and efficient representation of the underlying uncertainty. To achieve this, many current quantile-based methods focus on optimizing the so-called pinball loss. However, this loss restricts the scope of applicable regression models, limits the ability to target many desirable properties (e.g. calibration, sharpness, centered intervals), and may produce poor conditional quantiles. In this work, we develop new quantile methods that address these shortcomings. In particular, we propose methods that can apply to any class of regression model, allow for selecting a trade-off between calibration and sharpness, optimize for calibration of centered intervals, and produce more accurate conditional quantiles. We provide a thorough experimental evaluation of our methods, which includes a high dimensional uncertainty quantification task in nuclear fusion.
Cite
@article{arxiv.2011.09588,
title = {Beyond Pinball Loss: Quantile Methods for Calibrated Uncertainty Quantification},
author = {Youngseog Chung and Willie Neiswanger and Ian Char and Jeff Schneider},
journal= {arXiv preprint arXiv:2011.09588},
year = {2021}
}
Comments
Appears in Proceedings of the 35th Conference on Neural Information Processing Systems (NeurIPS 2021)