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Inductive simulation of calorimeter showers with normalizing flows

Matthew R. Buckley, Ian Pang, David Shih, Claudius Krause

2024Physical review. D/Physical review. D.31 citationsDOIOpen Access PDF

Abstract

Simulating particle detector response is the single most expensive step in the Large Hadron Collider computational pipeline. Recently it was shown that normalizing flows can accelerate this process while achieving unprecedented levels of accuracy, but scaling this approach up to higher resolutions relevant for future detector upgrades leads to prohibitive memory constraints. To overcome this problem, we introduce Inductive CaloFlow (icaloflow), a framework for fast detector simulation based on an inductive series of normalizing flows trained on the pattern of energy depositions in pairs of consecutive calorimeter layers. We further use a teacher-student distillation to increase sampling speed without loss of expressivity. As we demonstrate with datasets 2 and 3 of the CaloChallenge2022, icaloflow can realize the potential of normalizing flows in performing fast, high-fidelity simulation on detector geometries that are $\ensuremath{\sim}10--100$ times higher granularity than previously considered.

Topics & Concepts

Calorimeter (particle physics)GranularityDetectorPipeline (software)ScalingComputer scienceProcess (computing)High fidelityLarge Hadron ColliderEnergy (signal processing)PhysicsComputational scienceComputational physicsAlgorithmOpticsParticle physicsAcousticsMathematicsGeometryOperating systemProgramming languageQuantum mechanicsParticle physics theoretical and experimental studiesParticle Detector Development and PerformanceHigh-Energy Particle Collisions Research
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