Performance versus resilience in modern quark-gluon tagging
Anja Butter, Barry M. Dillon, Tilman Plehn, Lorenz Vogel
Abstract
Discriminating quark-like from gluon-like jets is, in many ways, a key challenge for many LHC analyses. First, we use a known difference in PYTHIA and HERWIG simulations to show how decorrelated taggers would break down when the most distinctive feature is aligned with theory uncertainties. We propose conditional training on interpolated samples, combined with a controlled Bayesian network, as a more resilient framework. The interpolation parameter can be used to optimize the training evaluated on a calibration dataset, and to test the stability of this optimization. The interpolated training might also be useful to track generalization errors when training networks on simulations.
Topics & Concepts
Interpolation (computer graphics)GeneralizationLarge Hadron ColliderStability (learning theory)Machine learningGluonCalibrationFeature (linguistics)Bayesian probabilityQuarkArtificial intelligenceComputer sciencePhysicsParticle physicsResilience (materials science)MathematicsThermodynamicsLinguisticsPhilosophyMotion (physics)Mathematical analysisQuantum mechanicsParticle physics theoretical and experimental studiesHigh-Energy Particle Collisions ResearchParticle Detector Development and Performance