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Compositional Generation for Long-Horizon Coupled PDEs

generative-ai › diffusion

📄 Abstract

Abstract: Simulating coupled PDE systems is computationally intensive, and prior efforts have largely focused on training surrogates on the joint (coupled) data, which requires a large amount of data. In the paper, we study compositional diffusion approaches where diffusion models are only trained on the decoupled PDE data and are composed at inference time to recover the coupled field. Specifically, we investigate whether the compositional strategy can be feasible under long time horizons involving a large number of time steps. In addition, we compare a baseline diffusion model with that trained using the v-parameterization strategy. We also introduce a symmetric compositional scheme for the coupled fields based on the Euler scheme. We evaluate on Reaction-Diffusion and modified Burgers with longer time grids, and benchmark against a Fourier Neural Operator trained on coupled data. Despite seeing only decoupled training data, the compositional diffusion models recover coupled trajectories with low error. v-parameterization can improve accuracy over a baseline diffusion model, while the neural operator surrogate remains strongest given that it is trained on the coupled data. These results show that compositional diffusion is a viable strategy towards efficient, long-horizon modeling of coupled PDEs.

Authors (3)

Somayajulu L. N. Dhulipala

Deep Ray

Nicholas Forman

Submitted

October 23, 2025

arXiv Category

stat.ML

arXiv PDF

Key Contributions

This paper proposes a compositional diffusion approach for simulating long-horizon coupled PDEs, where diffusion models are trained on decoupled data and composed at inference time. This significantly reduces data requirements compared to training on coupled data and demonstrates feasibility for long time horizons.

Business Value

Enables faster and more accurate simulations of complex physical phenomena, leading to improved design and optimization in fields like aerospace, climate science, and chemical engineering.

Paper Metadata

Innovation Type

Methodological Innovation

Deployment Feasibility

Moderate. Requires expertise in scientific machine learning and PDE solvers. Integration into existing simulation workflows is key.

Limitations Addressed

High data requirements for training surrogates on coupled PDE systems and computational intensity of simulating coupled PDEs over long time horizons.

Performance Gains

Recovers coupled trajectories despite seeing only decoupled training data; comparable to or better than models trained on coupled data.

Technical Tags

partial differential equations (PDEs)coupled systemsdiffusion modelscompositional generationsurrogate modelinglong time horizonsinference time compositionv-parameterizationEuler schemescientific machine learning

Research Topics

Scientific Machine LearningDifferential EquationsGenerative ModelsNumerical SimulationDeep Learning for Science

Methods & Architectures

Compositional Diffusion ModelsTraining on Decoupled DataInference-time Compositionv-parameterizationSymmetric Compositional SchemeEuler Scheme Diffusion ModelsFourier Neural Operator

Applications & Tasks

Physics Simulation Fluid Dynamics Climate Modeling Engineering Simulation Computational Science Simulating Coupled PDEsReducing Data Requirements for SurrogatesHandling Long Time HorizonsCompositional Modeling Recovering coupled PDE fields from decoupled trainingSimulating complex physical systems over long durationsDeveloping data-efficient surrogate models for PDEs

Datasets & Benchmarks

Benchmarks

Reaction-Diffusion • modified Burgers

Related Fields

Scientific Machine LearningPartial Differential EquationsGenerative ModelsDeep LearningNumerical AnalysisPhysics

Keywords

PDEsCoupled SystemsDiffusion ModelsCompositional GenerationSurrogate ModelingScientific Machine LearningLong Time HorizonsGenerative AINumerical SimulationReaction-DiffusionBurgers EquationFourier Neural Operator

Academic Context

#Scientific Machine Learning#Differential Equations#Generative Models#Numerical Simulation#Deep Learning for Science

Commercial Potential

Potential Products

High-fidelity simulation softwareAccelerated modeling tools for scientific researchDigital twins for complex systems

Target Industries

AerospaceAutomotiveEnergyClimate ScienceManufacturingResearch & Development

Use Case Examples

Simulating weather patterns over extended periodsModeling fluid dynamics in complex geometriesPredicting material behavior under stress

Competitive Edge

Offers a novel compositional approach that significantly reduces data requirements and computational cost for simulating complex, long-horizon coupled PDEs compared to traditional surrogate training methods.

Market Opportunity

Large market for scientific simulation and modeling software.

Revenue Models

Licensing of simulation softwarespecialized consulting services.

Resource Requirements

Compute Needs

High, especially for training diffusion models and running long simulations.

Data Requirements

Requires data for decoupled PDEs; less data needed than for coupled PDE surrogates.

Deployment Constraints

Generalization to unseen PDE systems, stability of long-horizon simulations, interpretability of compositional models.

Scalability

Scalability for long time horizons is a key focus; compositional approach aids in managing complexity.

Production Readiness

Maturity Level

Research

Time to Market

3-5 years for integration into specialized simulation software.

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