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E2Former: An Efficient and Equivariant Transformer with Linear-Scaling Tensor Products

graph-neural-networks › molecular-modeling

📄 Abstract

Abstract: Equivariant Graph Neural Networks (EGNNs) have demonstrated significant success in modeling microscale systems, including those in chemistry, biology and materials science. However, EGNNs face substantial computational challenges due to the high cost of constructing edge features via spherical tensor products, making them impractical for large-scale systems. To address this limitation, we introduce E2Former, an equivariant and efficient transformer architecture that incorporates the Wigner $6j$ convolution (Wigner $6j$ Conv). By shifting the computational burden from edges to nodes, the Wigner $6j$ Conv reduces the complexity from $O(|\mathcal{E}|)$ to $ O(| \mathcal{V}|)$ while preserving both the model's expressive power and rotational equivariance. We show that this approach achieves a 7x-30x speedup compared to conventional $\mathrm{SO}(3)$ convolutions. Furthermore, our empirical results demonstrate that the derived E2Former mitigates the computational challenges of existing approaches without compromising the ability to capture detailed geometric information. This development could suggest a promising direction for scalable and efficient molecular modeling.

Authors (13)

Yunyang Li

Lin Huang

Zhihao Ding

Chu Wang

Xinran Wei

Han Yang

+7 more

Submitted

January 31, 2025

arXiv Category

cs.LG

arXiv PDF

Key Contributions

Introduces E2Former, an efficient and equivariant transformer architecture that uses Wigner 6j convolution to reduce computational complexity from O(|E|) to O(|V|), enabling practical application of EGNNs to large-scale systems while preserving rotational equivariance. This results in significant speedups (7x-30x) compared to conventional SO(3) convolutions.

Business Value

Enables faster and more efficient simulations in drug discovery, materials design, and computational chemistry, accelerating research and development cycles. This can lead to quicker identification of new drugs, materials, and catalysts.

Paper Metadata

Innovation Type

Algorithmic Improvement

Deployment Feasibility

High, as it directly addresses computational bottlenecks, making advanced models more accessible.

Limitations Addressed

High computational cost of conventional EGNNs,Impracticality for large-scale systems,Complexity of spherical tensor products for edge features

Performance Gains

7x-30x speedup compared to conventional SO(3) convolutions

Technical Tags

Equivariant Graph Neural NetworksEGNNsTransformersTensor ProductsWigner 6j convolutionSO(3) convolutionsLinear ScalingRotational EquivarianceSpherical Tensor ProductsMicroscale Systems

Research Topics

Equivariant Deep LearningMolecular ModelingComputational ChemistryMaterials ScienceScalable EGNNsGeometric Deep Learning

Methods & Architectures

E2FormerWigner 6j convolutionSpherical tensor productsSO(3) convolutions E2FormerEquivariant Graph Neural Networks (EGNNs)Transformer

Applications & Tasks

Chemistry Biology Materials Science Microscale Systems High computational cost of EGNNsImpracticality for large-scale systemsEdge feature construction complexity Modeling microscale systemsPredicting molecular propertiesSimulating chemical reactions

Related Fields

Machine LearningDeep LearningComputational ChemistryMaterials ScienceGeometric Deep LearningPhysics-Informed AI

Keywords

Equivariant Graph Neural NetworksEGNNsTransformersWigner 6j convolutionMolecular ModelingMaterials ScienceChemistryComputational EfficiencyRotational EquivarianceLarge-scale SystemsGeometric Deep LearningTensor ProductsSO(3) Convolutions

Academic Context

#Equivariant Deep Learning#Molecular Modeling#Computational Chemistry#Materials Science#Scalable EGNNs#Geometric Deep Learning

Commercial Potential

Potential Products

Accelerated molecular simulation softwareDrug discovery platformsMaterials design tools

Target Industries

PharmaceuticalsBiotechnologyMaterials ScienceChemicalsEnergy

Use Case Examples

Predicting protein-ligand binding affinitiesDesigning novel catalystsSimulating material properties at the atomic level

Competitive Edge

Offers a computationally efficient and scalable alternative to existing EGNNs for large-scale molecular and microscale system modeling.

Market Opportunity

Significant market in computational chemistry and materials science software.

Revenue Models

Software licensingcloud-based simulation services.

Resource Requirements

Compute Needs

Potentially high, but significantly reduced compared to prior methods for large systems.

Data Requirements

Requires datasets relevant to chemistry, biology, and materials science.

Deployment Constraints

Requires specialized knowledge of equivariant models and potentially large datasets for training.

Scalability

Designed for linear scaling with the number of nodes, enabling scalability to larger systems.

Production Readiness

Maturity Level

Research

Time to Market

1-3 years for specialized applications.

Patent Potential

Moderate, particularly for the novel Wigner 6j convolution and E2Former architecture.

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