- Main
The Tracking Machine Learning Challenge: Accuracy Phase
- Amrouche, Sabrina;
- Basara, Laurent;
- Calafiura, Paolo;
- Estrade, Victor;
- Farrell, Steven;
- Ferreira, Diogo R;
- Finnie, Liam;
- Finnie, Nicole;
- Germain, Cécile;
- Gligorov, Vladimir Vava;
- Golling, Tobias;
- Gorbunov, Sergey;
- Gray, Heather;
- Guyon, Isabelle;
- Hushchyn, Mikhail;
- Innocente, Vincenzo;
- Kiehn, Moritz;
- Moyse, Edward;
- Puget, Jean-François;
- Reina, Yuval;
- Rousseau, David;
- Salzburger, Andreas;
- Ustyuzhanin, Andrey;
- Vlimant, Jean-Roch;
- Wind, Johan Sokrates;
- Xylouris, Trian;
- Yilmaz, Yetkin
- et al.
Published Web Location
https://doi.org/10.1007/978-3-030-29135-8_9Abstract
This paper reports the results of an experiment in high energy physics: using the power of the "crowd" to solve difficult experimental problems linked to tracking accurately the trajectory of particles in the Large Hadron Collider (LHC). This experiment took the form of a machine learning challenge organized in 2018: the Tracking Machine Learning Challenge (TrackML). Its results were discussed at the competition session at the Neural Information Processing Systems conference (NeurIPS 2018). Given 100.000 points, the participants had to connect them into about 10.000 arcs of circles, following the trajectory of particles issued from very high energy proton collisions. The competition was difficult with a dozen front-runners well ahead of a pack. The single competition score is shown to be accurate and effective in selecting the best algorithms from the domain point of view. The competition has exposed a diversity of approaches, with various roles for Machine Learning, a number of which are discussed in the document
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