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JUNIPR: a Framework for Unsupervised Machine Learning in Particle Physics

High Energy Physics - Phenomenology 2019-02-20 v1 Machine Learning

Abstract

In applications of machine learning to particle physics, a persistent challenge is how to go beyond discrimination to learn about the underlying physics. To this end, a powerful tool would be a framework for unsupervised learning, where the machine learns the intricate high-dimensional contours of the data upon which it is trained, without reference to pre-established labels. In order to approach such a complex task, an unsupervised network must be structured intelligently, based on a qualitative understanding of the data. In this paper, we scaffold the neural network's architecture around a leading-order model of the physics underlying the data. In addition to making unsupervised learning tractable, this design actually alleviates existing tensions between performance and interpretability. We call the framework JUNIPR: "Jets from UNsupervised Interpretable PRobabilistic models". In this approach, the set of particle momenta composing a jet are clustered into a binary tree that the neural network examines sequentially. Training is unsupervised and unrestricted: the network could decide that the data bears little correspondence to the chosen tree structure. However, when there is a correspondence, the network's output along the tree has a direct physical interpretation. JUNIPR models can perform discrimination tasks, through the statistically optimal likelihood-ratio test, and they permit visualizations of discrimination power at each branching in a jet's tree. Additionally, JUNIPR models provide a probability distribution from which events can be drawn, providing a data-driven Monte Carlo generator. As a third application, JUNIPR models can reweight events from one (e.g. simulated) data set to agree with distributions from another (e.g. experimental) data set.

Keywords

Cite

@article{arxiv.1804.09720,
  title  = {JUNIPR: a Framework for Unsupervised Machine Learning in Particle Physics},
  author = {Anders Andreassen and Ilya Feige and Christopher Frye and Matthew D. Schwartz},
  journal= {arXiv preprint arXiv:1804.09720},
  year   = {2019}
}

Comments

37 pages, 24 figures

R2 v1 2026-06-23T01:35:51.414Z