Neural Conditional Probability for Uncertainty Quantification

Vladimir R. Kostic; Karim Lounici; Grégoire Pacreau; Giacomo Turri; Pietro Novelli; Massimiliano Pontil

Neural Conditional Probability for Uncertainty Quantification

Vladimir R. Kostic
, Karim Lounici
, Grégoire Pacreau
, Giacomo Turri
, Pietro Novelli
, Massimiliano Pontil

Research output: Contribution to journal › Conference article › peer-review

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.

Original language	English
Journal	Advances in Neural Information Processing Systems
Volume	37
Publication status	Published - 1 Jan 2024
Event	38th Conference on Neural Information Processing Systems, NeurIPS 2024 - Vancouver, Canada Duration: 9 Dec 2024 → 15 Dec 2024

Cite this

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title = "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.",

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T1 - Neural Conditional Probability for Uncertainty Quantification

AU - Kostic, Vladimir R.

AU - Lounici, Karim

AU - Pacreau, Grégoire

AU - Turri, Giacomo

AU - Novelli, Pietro

AU - Pontil, Massimiliano

PY - 2024/1/1

Y1 - 2024/1/1

N2 - 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.

AB - 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.

UR - https://www.scopus.com/pages/publications/105000545893

M3 - Conference article

AN - SCOPUS:105000545893

SN - 1049-5258

VL - 37

JO - Advances in Neural Information Processing Systems

JF - Advances in Neural Information Processing Systems

T2 - 38th Conference on Neural Information Processing Systems, NeurIPS 2024

Y2 - 9 December 2024 through 15 December 2024

ER -

Neural Conditional Probability for Uncertainty Quantification

Abstract

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