arxiv_cv 88% Match Research Paper Computational Scientists,Physics Researchers,Mechanical Engineers,AI Researchers in Scientific Domains 2 weeks ago

Breaking the Discretization Barrier of Continuous Physics Simulation Learning

generative-ai › flow-models

📄 Abstract

Abstract: The modeling of complicated time-evolving physical dynamics from partial observations is a long-standing challenge. Particularly, observations can be sparsely distributed in a seemingly random or unstructured manner, making it difficult to capture highly nonlinear features in a variety of scientific and engineering problems. However, existing data-driven approaches are often constrained by fixed spatial and temporal discretization. While some researchers attempt to achieve spatio-temporal continuity by designing novel strategies, they either overly rely on traditional numerical methods or fail to truly overcome the limitations imposed by discretization. To address these, we propose CoPS, a purely data-driven methods, to effectively model continuous physics simulation from partial observations. Specifically, we employ multiplicative filter network to fuse and encode spatial information with the corresponding observations. Then we customize geometric grids and use message-passing mechanism to map features from original spatial domain to the customized grids. Subsequently, CoPS models continuous-time dynamics by designing multi-scale graph ODEs, while introducing a Markov-based neural auto-correction module to assist and constrain the continuous extrapolations. Comprehensive experiments demonstrate that CoPS advances the state-of-the-art methods in space-time continuous modeling across various scenarios.

Authors (7)

Fan Xu

Hao Wu

Nan Wang

Lilan Peng

Kun Wang

Wei Gong

+1 more

Submitted

September 22, 2025

arXiv Category

cs.CV

arXiv PDF

Key Contributions

This paper introduces CoPS, a purely data-driven method for modeling continuous physics simulations from partial observations. It overcomes the limitations of fixed discretization by employing multiplicative filter networks for spatial information fusion and customized geometric grids with message passing to capture complex, nonlinear dynamics.

Business Value

Enables faster and more accurate simulations of physical processes, reducing the need for computationally expensive traditional solvers. This can accelerate scientific discovery and engineering design cycles.

Paper Metadata

Innovation Type

Novel Methodology/Framework

Deployment Feasibility

Moderate. Requires expertise in physics and ML. Integration into existing simulation workflows may be complex.

Limitations Addressed

Constrained spatial and temporal discretization in existing data-driven approaches,Difficulty in capturing highly nonlinear features from sparse observations,Over-reliance on traditional numerical methods in some continuous simulation attempts

Technical Tags

Physics SimulationContinuous Time ModelingData-Driven MethodsPartial ObservationsMultiplicative Filter NetworksGeometric GridsMessage PassingNonlinear DynamicsScientific ComputingEngineering Problems

Research Topics

Physics-Informed Machine LearningScientific Machine LearningTime Series ModelingDynamical SystemsGenerative Modeling

Methods & Architectures

Multiplicative Filter NetworksGeometric GridsMessage PassingPurely Data-Driven Methods Multiplicative Filter Networks

Applications & Tasks

Scientific Simulation Engineering Analysis Fluid Dynamics Climate Modeling Materials Science Modeling Complex Time-Evolving Physical DynamicsHandling Sparsely Distributed ObservationsCapturing Highly Nonlinear FeaturesOvercoming Fixed Spatial/Temporal Discretization Limitations Continuous Physics Simulation LearningModeling Physical Dynamics from Partial ObservationsAccurate Prediction of Evolving Systems

Related Fields

Scientific ComputingPhysicsMachine LearningDynamical SystemsNumerical Methods

Keywords

physics simulationcontinuous timedata-driven modelingpartial observationsmultiplicative filtersgeometric gridsmessage passingnonlinear dynamicsscientific machine learningCoPS

Academic Context

#Physics-Informed Machine Learning#Scientific Machine Learning#Time Series Modeling#Dynamical Systems#Generative Modeling

Commercial Potential

Potential Products

Physics simulation softwareTools for accelerating engineering designPredictive modeling platforms for scientific phenomena

Target Industries

AerospaceAutomotiveEnergyMaterials SciencePharmaceuticals (drug discovery simulation)

Use Case Examples

Simulating fluid dynamics for aircraft designPredicting material behavior under stressModeling weather patterns or climate change effects

Competitive Edge

Offers a purely data-driven alternative to traditional numerical methods for continuous physics simulation, potentially achieving higher accuracy and efficiency, especially for complex nonlinear systems with sparse data.

Market Opportunity

Large market for simulation software in engineering and scientific research.

Revenue Models

Licensing of simulation softwareconsulting services for custom simulations.

Resource Requirements

Compute Needs

High (for training complex simulation models)

Data Requirements

Time-series data of physical systems, potentially with sparse spatial observations.

Deployment Constraints

Requires sufficient observational data. Validation against real-world physics is crucial. Interpretability of the learned dynamics.

Scalability

Scalability depends on the complexity of the physical system and the size of the learned model. Message passing can be parallelized.

Regulatory Considerations

N/A (focus on scientific modeling)

Production Readiness

Maturity Level

Research/Development

Time to Market

3-5 years

Patent Potential

Moderate (novel data-driven simulation methodology)

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