Does Lorentz-symmetric design boost network performance in jet physics?

IF 5 2区物理与天体物理 Q1 Physics and Astronomy

Physical Review D Pub Date : 2024-03-04 DOI:10.1103/physrevd.109.056003

Congqiao Li, Huilin Qu, Sitian Qian, Qi Meng, Shiqi Gong, Jue Zhang, Tie-Yan Liu, Qiang Li

引用次数: 0

Abstract

In the deep learning era, improving the neural network performance in jet physics is a rewarding task, as it directly contributes to more accurate physics measurements at the LHC. Recent research has proposed various network designs in consideration of the full Lorentz symmetry, but its benefit is still not systematically asserted, given that there remain many successful networks without taking it into account. We conduct a detailed study on the Lorentz-symmetric design. We propose two generalized approaches for modifying a network—these methods are experimented on Particle Flow Network, ParticleNet, and LorentzNet and exhibit a general performance gain. We also reveal that the notable improvement attributed to the “pairwise mass” feature in the network is due to its introduction of a structure that fully complies with Lorentz symmetry. We confirm that Lorentz-symmetry preservation serves as a strong inductive bias of jet physics, hence calling for attention to such general recipes in future network designs.

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洛伦兹对称设计能否提升喷射物理学的网络性能？

在深度学习时代，提高神经网络在射流物理中的性能是一项有意义的任务，因为它直接有助于在大型强子对撞机上进行更精确的物理测量。最近的研究提出了考虑完全洛伦兹对称性的各种网络设计，但由于仍有许多成功的网络没有考虑洛伦兹对称性，因此它的好处仍未得到系统的论证。我们对洛伦兹对称设计进行了详细研究。我们提出了两种修改网络的通用方法，并在粒子流网络、粒子网络和洛伦兹网络上对这些方法进行了实验，结果表明这些方法普遍提高了性能。我们还发现，网络中的 "成对质量 "特征之所以能带来显著改进，是因为它引入了完全符合洛伦兹对称性的结构。我们证实，洛伦兹对称性的保持是射流物理学的一个强有力的归纳偏向，因此呼吁在未来的网络设计中关注这种通用配方。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Physical Review D 物理-天文与天体物理

CiteScore

9.20

自引率

36.00%

发文量

审稿时长

2 months

期刊介绍： Physical Review D (PRD) is a leading journal in elementary particle physics, field theory, gravitation, and cosmology and is one of the top-cited journals in high-energy physics. PRD covers experimental and theoretical results in all aspects of particle physics, field theory, gravitation and cosmology, including: Particle physics experiments, Electroweak interactions, Strong interactions, Lattice field theories, lattice QCD, Beyond the standard model physics, Phenomenological aspects of field theory, general methods, Gravity, cosmology, cosmic rays, Astrophysics and astroparticle physics, General relativity, Formal aspects of field theory, field theory in curved space, String theory, quantum gravity, gauge/gravity duality.