Particle Graph Autoencoders and Differentiable, Learned Energy Mover's Distance

Steven Tsan, Raghav Kansal, Anthony Aportela, Daniel Diaz, Javier Duarte, Sukanya Krishna, Farouk Mokhtar, Jean-Roch Vlimant, Maurizio Pierini
December, 2021
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Abstract

Autoencoders have useful applications in high energy physics in anomaly detection, particularly for jets - collimated showers of particles produced in collisions such as those at the CERN Large Hadron Collider. We explore the use of graph-based autoencoders, which operate on jets in their “particle cloud” representations and can leverage the interdependencies among the particles within a jet, for such tasks. Additionally, we develop a differentiable approximation to the energy mover’s distance via a graph neural network, which may subsequently be used as a reconstruction loss function for autoencoders.

Type
Conference paper
Publication
Fourth Workshop on Machine Learning and the Physical Sciences @ NeurIPS 2021
ML Equivariant and Physics-Informed ML Anomaly Detection
Raghav Kansal
Raghav Kansal
PhD Candidate in Particle Physics and Machine Learning