中文

Signal Confidence Limits from a Neural Network Data Analysis

高能物理 - 实验 2016-08-31 v2 高能物理 - 唯象学

摘要

This paper deals with a situation of some importance for the analysis of experimental data via Neural Network (NN) or similar devices: Let NN data be given, such that N=Ns+NbN=N_s+N_b, where NsN_s is the number of signals, NbN_b the number of background events, both unknown. Assume that a NN has been trained, such that it will tag signals with efficiency FsF_s, (0<Fs<1)(0<F_s<1) and background data with FbF_b, (0<Fb<1)(0<F_b<1). Applying the NN yields NYN^Y tagged events. We demonstrate that the knowledge of NYN^Y is sufficient to calculate confidence bounds for the signal likelihood, which have the same statistical interpretation as the Clopper-Pearson bounds for the well-studied case of direct signal observation. Subsequently, we discuss rigorous bounds for the a-posteriori distribution function of the signal probability, as well as for the (closely related) likelihood that there are NsN_s signals in the data. We compare them with results obtained by starting off with a maximum entropy type assumption for the a-priori likelihood that there are NsN_s signals in the data and applying the Bayesian theorem. Difficulties are encountered with the latter method.

关键词

引用

@article{arxiv.hep-ex/9703001,
  title  = {Signal Confidence Limits from a Neural Network Data Analysis},
  author = {B. Berg and J. Riedler},
  journal= {arXiv preprint arXiv:hep-ex/9703001},
  year   = {2016}
}

备注

17 pages, 10 eps figures, LaTeX, major revisions due to referee Report