End-to-End Detector Optimization with Diffusion models: A Case Study in Sampling Calorimeters
Abstract
Recent advances in machine learning have opened new avenues for optimizing detector designs in high-energy physics, where the complex interplay of geometry, materials, and physics processes has traditionally posed a significant challenge. In this work, we introduce the AI Detector Optimization framework (AIDO) that leverages a diffusion model as a surrogate for the full simulation and reconstruction chain, enabling gradient-based design exploration in both continuous and discrete parameter spaces. Although this framework is applicable to a broad range of detectors, we illustrate its power using the specific example of a sampling calorimeter, focusing on charged pions and photons as representative incident particles. Our results demonstrate that the diffusion model effectively captures critical performance metrics for calorimeter design, guiding the automatic search for layer arrangement and material composition that aligns with known calorimeter principles. The success of this proof-of-concept study provides a foundation for future applications of end-to-end optimization to more complex detector systems, offering a promising path toward systematically exploring the vast design space in next-generation experiments.
Cite
@article{arxiv.2502.02152,
title = {End-to-End Detector Optimization with Diffusion models: A Case Study in Sampling Calorimeters},
author = {Kylian Schmidt and Nikhil Kota and Jan Kieseler and Andrea De Vita and Markus Klute and Abhishek and Max Aehle and Muhammad Awais and Alessandro Breccia and Riccardo Carroccio and Long Chen and Tommaso Dorigo and Nicolas R. Gauger and Enrico Lupi and Federico Nardi and Xuan Tung Nguyen and Fredrik Sandin and Joseph Willmore and Pietro Vischia},
journal= {arXiv preprint arXiv:2502.02152},
year = {2026}
}
Comments
15 pages, 9 figures, submitted to MDPI particles