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Autores principales: Zheng, Ruoqing, Sun, Chang, Liu, Qibin, Laatu, Lauri, Cox, Arianna, Maier, Benedikt, Tapper, Alexander, Coutinho, Jose G. F., Luk, Wayne, Que, Zhiqiang
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2601.17215
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author Zheng, Ruoqing
Sun, Chang
Liu, Qibin
Laatu, Lauri
Cox, Arianna
Maier, Benedikt
Tapper, Alexander
Coutinho, Jose G. F.
Luk, Wayne
Que, Zhiqiang
author_facet Zheng, Ruoqing
Sun, Chang
Liu, Qibin
Laatu, Lauri
Cox, Arianna
Maier, Benedikt
Tapper, Alexander
Coutinho, Jose G. F.
Luk, Wayne
Que, Zhiqiang
contents We present JetFormer, a versatile and scalable encoder-only Transformer architecture for particle jet tagging at the Large Hadron Collider (LHC). Unlike prior approaches that are often tailored to specific deployment regimes, JetFormer is designed to operate effectively across the full spectrum of jet tagging scenarios, from high-accuracy offline analysis to ultra-low-latency online triggering. The model processes variable-length sets of particle features without relying on input of explicit pairwise interactions, yet achieves competitive or superior performance compared to state-of-the-art methods. On the large-scale JetClass dataset, a large-scale JetFormer matches the accuracy of the interaction-rich ParT model (within 0.7%) while using 37.4% fewer FLOPs, demonstrating its computational efficiency and strong generalization. On benchmark HLS4ML 150P datasets, JetFormer consistently outperforms existing models such as MLPs, Deep Sets, and Interaction Networks by 3-4% in accuracy. To bridge the gap to hardware deployment, we further introduce a hardware-aware optimization pipeline based on multi-objective hyperparameter search, yielding compact variants like JetFormer-tiny suitable for FPGA-based trigger systems with sub-microsecond latency requirements. Through structured pruning and quantization, we show that JetFormer can be aggressively compressed with minimal accuracy loss. By unifying high-performance modeling and deployability within a single architectural framework, JetFormer provides a practical pathway for deploying Transformer-based jet taggers in both offline and online environments at the LHC. Code is available at https://github.com/walkieq/JetFormer.
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spellingShingle JetFormer: A Scalable and Efficient Transformer for Jet Tagging from Offline Analysis to FPGA Triggers
Zheng, Ruoqing
Sun, Chang
Liu, Qibin
Laatu, Lauri
Cox, Arianna
Maier, Benedikt
Tapper, Alexander
Coutinho, Jose G. F.
Luk, Wayne
Que, Zhiqiang
Machine Learning
High Energy Physics - Experiment
We present JetFormer, a versatile and scalable encoder-only Transformer architecture for particle jet tagging at the Large Hadron Collider (LHC). Unlike prior approaches that are often tailored to specific deployment regimes, JetFormer is designed to operate effectively across the full spectrum of jet tagging scenarios, from high-accuracy offline analysis to ultra-low-latency online triggering. The model processes variable-length sets of particle features without relying on input of explicit pairwise interactions, yet achieves competitive or superior performance compared to state-of-the-art methods. On the large-scale JetClass dataset, a large-scale JetFormer matches the accuracy of the interaction-rich ParT model (within 0.7%) while using 37.4% fewer FLOPs, demonstrating its computational efficiency and strong generalization. On benchmark HLS4ML 150P datasets, JetFormer consistently outperforms existing models such as MLPs, Deep Sets, and Interaction Networks by 3-4% in accuracy. To bridge the gap to hardware deployment, we further introduce a hardware-aware optimization pipeline based on multi-objective hyperparameter search, yielding compact variants like JetFormer-tiny suitable for FPGA-based trigger systems with sub-microsecond latency requirements. Through structured pruning and quantization, we show that JetFormer can be aggressively compressed with minimal accuracy loss. By unifying high-performance modeling and deployability within a single architectural framework, JetFormer provides a practical pathway for deploying Transformer-based jet taggers in both offline and online environments at the LHC. Code is available at https://github.com/walkieq/JetFormer.
title JetFormer: A Scalable and Efficient Transformer for Jet Tagging from Offline Analysis to FPGA Triggers
topic Machine Learning
High Energy Physics - Experiment
url https://arxiv.org/abs/2601.17215