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Denoising diffusion models with geometry adaptation for high fidelity calorimeter simulation

O. Amram, K. Pedro

2023Physical review. D/Physical review. D.36 citationsDOIOpen Access PDF

Abstract

Simulation is crucial for all aspects of collider data analysis, but the available computing budget in the High Luminosity LHC era will be severely constrained. Generative machine learning models may act as surrogates to replace physics-based full simulation of particle detectors, and diffusion models have recently emerged as the state of the art for other generative tasks. We introduce CaloDiffusion, a denoising diffusion model trained on the public CaloChallenge datasets to generate calorimeter showers. Our algorithm employs 3D cylindrical convolutions, which take advantage of symmetries of the underlying data representation. To handle irregular detector geometries, we augment the diffusion model with a new geometry latent mapping (GLaM) layer to learn forward and reverse transformations to a regular geometry that is suitable for cylindrical convolutions. The showers generated by our approach are nearly indistinguishable from the full simulation, as measured by several different metrics.

Topics & Concepts

Large Hadron ColliderDiffusionCalorimeter (particle physics)Computer scienceRepresentation (politics)Generative modelNoise reductionDetectorAlgorithmComputational scienceGeometryArtificial intelligencePhysicsGenerative grammarParticle physicsMathematicsPolitical scienceTelecommunicationsThermodynamicsPoliticsLawParticle physics theoretical and experimental studiesParticle Detector Development and PerformanceHigh-Energy Particle Collisions Research
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