Abstract
One of the most important aspects of data analysis at the LHC experiments is the particle identification (PID). In LHCb, several different sub-detectors provide PID information: two Ring Imaging Cherenkov (RICH) detectors, the hadronic and electromagnetic calorimeters, and the muon chambers. To improve charged particle identification, we have developed models based on deep learning and gradient boosting. The new approaches, tested on simulated samples, provide higher identification performances than the current solution for all charged particle types. It is also desirable to achieve a flat dependency of efficiencies from spectator variables such as particle momentum, in order to reduce systematic uncertainties in the physics results. For this purpose, models that improve the flatness property for efficiencies have also been developed. This paper presents this new approach and its performance.
Highlights
Particle identification (PID) plays a crucial role in LHCb [1] analyses
The LHCb PID system is composed of a tracking system, two ring-imaging Cherenkov detectors (RICH), electromagnetic (ECAL) and hadron (HCAL) calorimeters and a series of muon chambers
Global PID at LHCb identifies the charged particle type associated with a given track
Summary
Particle identification (PID) plays a crucial role in LHCb [1] analyses. The LHCb PID system is composed of a tracking system, two ring-imaging Cherenkov detectors (RICH), electromagnetic (ECAL) and hadron (HCAL) calorimeters and a series of muon chambers. Combining information from these subdetectors allows one to distinguish between various species of long-lived charged particles. Advanced machine learning techniques are employed to obtain the best PID performance and control systematic uncertainties in a data-driven way
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