Neural Conditional Probability for Uncertainty Quantification
Abstract
We introduce Neural Conditional Probability (NCP), an operator-theoretic approach to learning conditional distributions with a focus on statistical inference tasks. NCP can be used to build conditional confidence regions and extract key statistics such as conditional quantiles, mean, and covariance. It offers streamlined learning via a single unconditional training phase, allowing efficient inference without the need for retraining even when conditioning changes. By leveraging the approximation capabilities of neural networks, NCP efficiently handles a wide variety of complex probability distributions. We provide theoretical guarantees that ensure both optimization consistency and statistical accuracy. In experiments, we show that NCP with a 2-hidden-layer network matches or outperforms leading methods. This demonstrates that a a minimalistic architecture with a theoretically grounded loss can achieve competitive results, even in the face of more complex architectures.
Cite
@article{arxiv.2407.01171,
title = {Neural Conditional Probability for Uncertainty Quantification},
author = {Vladimir R. Kostic and Karim Lounici and Gregoire Pacreau and Pietro Novelli and Giacomo Turri and Massimiliano Pontil},
journal= {arXiv preprint arXiv:2407.01171},
year = {2025}
}
Comments
Advances in Neural Information Processing Systems (NeurIPS) 2024