Your search keyword '"LingGe, Li"' showing total 2 results

1. Efficient neutrino oscillation parameter inference using Gaussian processes.

Author

Lingge Li, Nayak, Nitish, Jianming Bian, and Baldi, Pierre

Subjects

*NEUTRINO oscillation, *GAUSSIAN processes, *INFERENTIAL statistics, *CONFIDENCE intervals, *PARTICLE physics

Abstract

The unified approach of Feldman and Cousins allows for exact statistical inference of small signals that commonly arise in high energy physics. It has gained widespread use, for instance, in measurements of neutrino oscillation parameters in long-baseline experiments. However, the approach relies on the Neyman construction of the classical confidence interval and is computationally intensive as it is typically done in a grid-based fashion over the entire parameter space. In this article, we propose an efficient algorithm for the Feldman-Cousins approach using Gaussian processes to construct confidence intervals iteratively. We show that in the neutrino oscillation context, one can obtain confidence intervals fives times faster in one dimension and ten times faster in two dimensions, while maintaining an accuracy above 99.5%. [ABSTRACT FROM AUTHOR]

Published

2020

2. Improved energy reconstruction in NOvA with regression convolutional neural networks.

Author

Baldi, Pierre, Jianming Bian, Hertel, Lars, and Lingge Li

Subjects

*NEUTRINOS, *REGRESSION analysis, *DIFFERENTIAL cross sections

Abstract

In neutrino experiments, neutrino energy reconstruction is crucial because neutrino oscillations and differential cross-sections are functions of neutrino energy. It is also challenging due to the complexity in the detector response and kinematics of final state particles. We propose a regression convolutional neural network (CNN) based method to reconstruct electron neutrino energy and electron energy in the NOvA neutrino experiment. We demonstrate that with raw detector pixel inputs, a regression CNN can reconstruct event energy even with complicated final states involving lepton and hadrons. Compared with kinematics-based energy reconstruction, this method achieves a significantly better energy resolution. The reconstructed to true energy ratio shows comparable or less dependence on true energy, hadronic energy fractions, and interaction modes. The regression CNN also shows smaller systematic uncertainties from the simulation of neutrino interactions. The proposed energy estimator provides improvements of 16% and 12% in RMS for νe CC and electron, respectively. This method can also be extended to solve other regression problems in High Energy Physics, taking over kinematics-based reconstruction tasks. [ABSTRACT FROM AUTHOR]

Published

2019