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Main Authors: Anderson, Derek, Bashyal, Amit, Diefenthaler, Markus, Fanelli, Cristiano, Guan, Wen, Horn, Tanja, Lin, Alex Jentsch Meifeng, Maeno, Tadashi, Nagai, Kei, Nayak, Hemalata, Pecar, Connor, Suresh, Karthik, Tsai, Fang-Ying, Vossen, Anselm, Wang, Tianle, Wenaus, Torre
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.30014
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author Anderson, Derek
Bashyal, Amit
Diefenthaler, Markus
Fanelli, Cristiano
Guan, Wen
Horn, Tanja
Lin, Alex Jentsch Meifeng
Maeno, Tadashi
Nagai, Kei
Nayak, Hemalata
Pecar, Connor
Suresh, Karthik
Tsai, Fang-Ying
Vossen, Anselm
Wang, Tianle
Wenaus, Torre
author_facet Anderson, Derek
Bashyal, Amit
Diefenthaler, Markus
Fanelli, Cristiano
Guan, Wen
Horn, Tanja
Lin, Alex Jentsch Meifeng
Maeno, Tadashi
Nagai, Kei
Nayak, Hemalata
Pecar, Connor
Suresh, Karthik
Tsai, Fang-Ying
Vossen, Anselm
Wang, Tianle
Wenaus, Torre
contents The Production and Distributed Analysis (PanDA) system, originally developed for the ATLAS experiment at the CERN Large Hadron Collider (LHC), has evolved into a robust platform for orchestrating large-scale workflows across distributed computing resources. Coupled with its intelligent Distributed Dispatch and Scheduling (iDDS) component, PanDA supports AI/ML-driven workflows through a scalable and flexible workflow engine. We present an AI-assisted framework for detector design optimization that integrates multi-objective Bayesian optimization with the PanDA--iDDS workflow engine to coordinate iterative simulations across heterogeneous resources. The framework addresses the challenge of exploring high-dimensional parameter spaces inherent in modern detector design. We demonstrate the framework using benchmark problems and realistic studies of the ePIC and dRICH detectors for the Electron-Ion Collider (EIC). Results show improved automation, scalability, and efficiency in multi-objective optimization. This work establishes a flexible and extensible paradigm for AI-driven detector design and other computationally intensive scientific applications.
format Preprint
id arxiv_https___arxiv_org_abs_2603_30014
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Scalable AI-assisted Workflow Management for Detector Design Optimization Using Distributed Computing
Anderson, Derek
Bashyal, Amit
Diefenthaler, Markus
Fanelli, Cristiano
Guan, Wen
Horn, Tanja
Lin, Alex Jentsch Meifeng
Maeno, Tadashi
Nagai, Kei
Nayak, Hemalata
Pecar, Connor
Suresh, Karthik
Tsai, Fang-Ying
Vossen, Anselm
Wang, Tianle
Wenaus, Torre
Distributed, Parallel, and Cluster Computing
Artificial Intelligence
The Production and Distributed Analysis (PanDA) system, originally developed for the ATLAS experiment at the CERN Large Hadron Collider (LHC), has evolved into a robust platform for orchestrating large-scale workflows across distributed computing resources. Coupled with its intelligent Distributed Dispatch and Scheduling (iDDS) component, PanDA supports AI/ML-driven workflows through a scalable and flexible workflow engine. We present an AI-assisted framework for detector design optimization that integrates multi-objective Bayesian optimization with the PanDA--iDDS workflow engine to coordinate iterative simulations across heterogeneous resources. The framework addresses the challenge of exploring high-dimensional parameter spaces inherent in modern detector design. We demonstrate the framework using benchmark problems and realistic studies of the ePIC and dRICH detectors for the Electron-Ion Collider (EIC). Results show improved automation, scalability, and efficiency in multi-objective optimization. This work establishes a flexible and extensible paradigm for AI-driven detector design and other computationally intensive scientific applications.
title Scalable AI-assisted Workflow Management for Detector Design Optimization Using Distributed Computing
topic Distributed, Parallel, and Cluster Computing
Artificial Intelligence
url https://arxiv.org/abs/2603.30014