arxiv_ml 95% Match Research Paper High Energy Physicists,ML Researchers in Scientific Computing,Data Analysts in Physics 1 day ago

Scalable Multi-Task Learning for Particle Collision Event Reconstruction with Heterogeneous Graph Neural Networks

graph-neural-networks › graph-learning

📄 Abstract

Abstract: The growing luminosity frontier at the Large Hadron Collider is challenging the reconstruction and analysis of particle collision events. Increased particle multiplicities are straining latency and storage requirements at the data acquisition stage, while new complications are emerging, including higher background levels and more frequent particle vertex misassociations. This in turn necessitates the development of more holistic and scalable reconstruction methods that take advantage of recent advances in machine learning. We propose a novel Heterogeneous Graph Neural Network (HGNN) architecture featuring unique representations for diverse particle collision relationships and integrated graph pruning layers for scalability. Trained with a multi-task paradigm in an environment mimicking the LHCb experiment, this HGNN significantly improves beauty hadron reconstruction performance. Notably, it concurrently performs particle vertex association and graph pruning within a single framework. We quantify reconstruction and pruning performance, demonstrate enhanced inference time scaling with event complexity, and mitigate potential performance loss using a weighted message passing scheme.

Authors (8)

William Sutcliffe

Marta Calvi

Simone Capelli

Jonas Eschle

Julián García Pardiñas

Abhijit Mathad

+2 more

Submitted

April 30, 2025

arXiv Category

physics.data-an

arXiv PDF

Key Contributions

Proposes a novel Heterogeneous Graph Neural Network (HGNN) architecture with unique representations and integrated graph pruning for scalable particle collision event reconstruction. Trained with multi-task learning, it significantly improves beauty hadron reconstruction and concurrently performs vertex association and pruning.

Business Value

Enables more efficient and accurate analysis of data from particle accelerators like the LHC, potentially leading to new scientific discoveries and advancements in fundamental physics.

Paper Metadata

Innovation Type

Novel Architecture/Methodology

Deployment Feasibility

Moderate. Requires specialized hardware and software environments typical of high-energy physics research, but the HGNN approach is designed for scalability.

Limitations Addressed

The increasing complexity and data volume from the LHC, which strains existing reconstruction methods, particularly regarding latency, storage, and particle vertex misassociations.

Performance Gains

Significant improvement in beauty hadron reconstruction performance.,Concurrent performance of vertex association and graph pruning.

Technical Tags

Heterogeneous Graph Neural Networksparticle collision eventsLarge Hadron Collider (LHC)event reconstructionmulti-task learninggraph pruningHGNNLHCb experimentbeauty hadron reconstructionparticle vertex association

Research Topics

Graph Neural NetworksHigh Energy PhysicsParticle PhysicsEvent ReconstructionMulti-Task Learning

Methods & Architectures

Heterogeneous Graph Neural Network (HGNN) architectureUnique representations for particle relationshipsIntegrated graph pruning layersMulti-task learning paradigm Heterogeneous Graph Neural Network (HGNN)

Applications & Tasks

High Energy Physics Particle Physics Research Scientific Computing Challenges in particle collision event reconstruction at LHCIncreased particle multiplicitiesLatency and storage requirementsParticle vertex misassociations Reconstruction and analysis of particle collision eventsBeauty hadron reconstructionParticle vertex associationGraph pruning for scalability

Related Fields

Graph Neural NetworksHigh Energy PhysicsMachine LearningScientific ComputingData Analysis

Keywords

GNNHGNNparticle physicsLHCevent reconstructionmulti-task learninggraph pruningvertex associationhigh energy physicsscientific machine learning

Academic Context

LHCb experiment #Graph Neural Networks#High Energy Physics#Particle Physics#Event Reconstruction#Multi-Task Learning

Companies & Organizations

Research Institutions

LHCb experiment

Commercial Potential

Potential Products

Advanced event reconstruction software for particle physicsData analysis tools for scientific research

Target Industries

Scientific ResearchAcademiaParticle PhysicsHigh-Performance Computing

Use Case Examples

Analyzing collision data from the Large Hadron Collider with higher precision and speed.Identifying rare particle events more effectively.Improving the efficiency of data processing pipelines in physics experiments.

Competitive Edge

Offers a novel HGNN architecture specifically designed for the complex, heterogeneous data of particle collisions, incorporating scalability features like graph pruning.

Market Opportunity

Niche but critical market within scientific research.

Revenue Models

N/A (primarily academic research)

Resource Requirements

Compute Needs

High (for training and inference on large physics datasets)

Data Requirements

Simulated and real particle collision event data.

Deployment Constraints

Integration with existing physics analysis frameworks, computational resources at research facilities.

Scalability

Graph pruning layers are explicitly designed for scalability.

Production Readiness

Maturity Level

Research

Time to Market

2-5 years (for integration into experimental pipelines)

Patent Potential

Low (primarily scientific methodology)

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