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Neural embedding: learning the embedding of the manifold of physics data

Sang Eon Park, Philip Harris, Bryan Ostdiek

2023Journal of High Energy Physics16 citationsDOIOpen Access PDF

Abstract

A bstract In this paper, we present a method of embedding physics data manifolds with metric structure into lower dimensional spaces with simpler metrics, such as Euclidean and Hyperbolic spaces. We then demonstrate that it can be a powerful step in the data analysis pipeline for many applications. Using progressively more realistic simulated collisions at the Large Hadron Collider, we show that this embedding approach learns the underlying latent structure. With the notion of volume in Euclidean spaces, we provide for the first time a viable solution to quantifying the true search capability of model agnostic search algorithms in collider physics (i.e. anomaly detection). Finally, we discuss how the ideas presented in this paper can be employed to solve many practical challenges that require the extraction of physically meaningful representations from information in complex high dimensional datasets.

Topics & Concepts

EmbeddingPhysicsPipeline (software)Euclidean geometryMetric (unit)Manifold (fluid mechanics)Particle physicsTheoretical computer scienceTheoretical physicsArtificial intelligenceComputer scienceMathematicsOperations managementMechanical engineeringEconomicsEngineeringGeometryProgramming languageComputational Physics and Python ApplicationsParticle physics theoretical and experimental studiesAnomaly Detection Techniques and Applications
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