Study of using machine learning for level 1 trigger decision in JUNO experiment

TL;DR

This paper explores using a machine learning-based level 1 trigger for the JUNO neutrino experiment, achieving high efficiency with less resource use by implementing a neural network in FPGA hardware.

Contribution

It introduces a neural network approach for trigger decision-making in JUNO, demonstrating high efficiency and successful FPGA implementation as an alternative to traditional vertex reconstruction.

Findings

MLP-based trigger achieves over 99% efficiency for >100 keV events

Successful FPGA implementation of the neural network model

Potential resource savings compared to existing algorithms

Abstract

A study on the use of a machine learning algorithm for the level 1 trigger decision in the JUNO experiment ispresented. JUNO is a medium baseline neutrino experiment in construction in China, with the main goal of determining the neutrino mass hierarchy. A large liquid scintillator (LS)volume will detect the electron antineutrinos issued from nuclear reactors. The LS detector is instrumented by around 20000 large photomultiplier tubes. The hit information from each PMT will be collected into a center trigger unit for the level 1 trigger decision. The current trigger algorithm used to select a neutrino signal event is based on a fast vertex reconstruction. We propose to study an alternative level 1 (L1) trigger in order to achieve a similar performance as the vertex fitting trigger but with less logic resources by using firmware implemented machine learning model at the L1 trigger level. We treat the trigger decision as a classification problem and train a Multi-Layer Perceptron (MLP)model to distinguish the signal events with an energy higher than a certain threshold from noise events. We use JUNO software to generate datasets which include 100K physics events with noise and 100K pure noise events coming from PMT dark noise.For events with energy higher than 100 keV, the L1 trigger based on the converged MLP model can achieve an efficiency higher than 99%. After the training performed on simulations,we successfully implemented the trained model into a Kintex 7FPGA. We present the technical details of the neural network development and training, as well as its implementation in the hardware with the FPGA programming. Finally the performance of the L1 trigger MLP implementation is discussed.