arxiv_ml 88% Match Research Paper Forecasting practitioners,ML engineers,Researchers in probabilistic modeling,Operations researchers 20 hours ago

End-to-End Probabilistic Framework for Learning with Hard Constraints

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📄 Abstract

Abstract: We present ProbHardE2E, a probabilistic forecasting framework that incorporates hard operational/physical constraints, and provides uncertainty quantification. Our methodology uses a novel differentiable probabilistic projection layer (DPPL) that can be combined with a wide range of neural network architectures. DPPL allows the model to learn the system in an end-to-end manner, compared to other approaches where constraints are satisfied either through a post-processing step or at inference. ProbHardE2E optimizes a strictly proper scoring rule, without making any distributional assumptions on the target, which enables it to obtain robust distributional estimates (in contrast to existing approaches that generally optimize likelihood-based objectives, which are heavily biased by their distributional assumptions and model choices); and it can incorporate a range of non-linear constraints (increasing the power of modeling and flexibility). We apply ProbHardE2E in learning partial differential equations with uncertainty estimates and to probabilistic time-series forecasting, showcasing it as a broadly applicable general framework that connects these seemingly disparate domains.

Key Contributions

Introduces ProbHardE2E, an end-to-end probabilistic forecasting framework that integrates hard operational/physical constraints and provides uncertainty quantification. It utilizes a novel differentiable probabilistic projection layer (DPPL) and optimizes scoring rules, enabling robust distributional estimates without strong distributional assumptions. This allows for learning complex systems with non-linear constraints in an end-to-end manner.

Business Value

Enables more reliable and actionable forecasts for systems with strict operational limits, leading to better resource management, risk assessment, and decision-making in industries like energy and finance.

Paper Metadata

Innovation Type

Algorithmic Improvement

Deployment Feasibility

Moderate. Requires integration into existing forecasting pipelines and potentially significant data for training.

Limitations Addressed

Difficulty in incorporating hard constraints into probabilistic forecasting models, reliance on restrictive distributional assumptions, and issues with likelihood-based objectives.

Technical Tags

probabilistic forecastinghard constraintsuncertainty quantificationdifferentiable probabilistic projection layer (DPPL)end-to-end learningscoring rulesnon-linear constraintsneural networksdistributional estimatestime-series

Research Topics

Probabilistic ModelingForecastingConstraint SatisfactionMachine LearningUncertainty Quantification

Methods & Architectures

Differentiable Probabilistic Projection Layer (DPPL)Optimization of strictly proper scoring rulesEnd-to-end learning with hard constraints Neural Networks

Applications & Tasks

Time-Series Forecasting Operations Research Energy Systems Finance Forecasting with hard constraintsProviding reliable uncertainty estimatesLearning complex system dynamics Probabilistic forecastingPredicting system behavior under operational constraints

Related Fields

Time Series AnalysisMachine LearningOperations ResearchControl TheoryStatistics

Keywords

probabilistic forecastinghard constraintsuncertainty quantificationdifferentiablescoring rulesneural networksend-to-endtime seriesDPPLnon-linear constraintsoperations research

Academic Context

#Probabilistic Modeling#Forecasting#Constraint Satisfaction#Machine Learning#Uncertainty Quantification

Commercial Potential

Potential Products

Constrained forecasting softwareRisk assessment tools for operational systemsEnergy load forecasting platforms

Target Industries

EnergyFinanceManufacturingLogisticsUtilities

Use Case Examples

Forecasting electricity demand while respecting generation capacityPredicting inventory levels within supply chain constraintsModeling financial markets with regulatory limits

Competitive Edge

Provides a more robust and flexible approach to constrained forecasting compared to traditional methods or post-processing techniques.

Market Opportunity

Large market for forecasting and predictive analytics solutions.

Revenue Models

SaaS for forecastinglicensing of the DPPL component.

Resource Requirements

Compute Needs

Moderate to High (for training neural networks)

Data Requirements

Time-series data, knowledge of operational/physical constraints.

Deployment Constraints

Requires accurate constraint definitions; training data quality is crucial.

Scalability

Scales with the complexity of the neural network architecture and the size of the time-series data.

Production Readiness

Maturity Level

Research

Time to Market

2-4 years (for integration into specialized forecasting tools)

Patent Potential

Moderate (novel differentiable layer)

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