Abstract: The NEutron Detector Array (NEDA) is designed to be coupled to gamma-ray spectrometers to enhance the sensitivity of the setup by enabling reaction channel selection through counting of the evaporated neutrons. This article presents the implementation of a double trigger condition system for NEDA, which improves the acquisition of neutrons and reduces the number of gamma rays acquired. Two independent triggers are generated in the double trigger condition system: one based on charge comparison (CC) and the other on time-of-flight (TOF). These triggers can be combined using OR and AND logic, offering four distinct trigger modes. The developed firmware is added to the previous one in the Virtex 6 field programmable gate array (FPGA) present in the system, which also includes signal processing, baseline correction, and various trigger logic blocks. The performance of the trigger system is evaluated using data from the E703 experiment performed at GANIL. The four trigger modes are applied to the same data, and a subsequent offline analysis is performed. It is shown that most of the detected neutrons are preserved with the AND mode, and the total number of gamma rays is significantly reduced. Compared with the CC trigger mode, the OR trigger mode allows increasing the selection of neutrons. In addition, it is demonstrated that if the OR mode is selected, the online CC trigger threshold can be raised without losing neutrons.

Abstract: This paper presents the design of the NEDA (Neutron Detector Array) electronics, a first attempt to involve the use of digital electronics in large neutron detector arrays. Starting from the front-end modules attached to the PMTs (PhotoMultiplier Tubes) and ending up with the data processing workstations, a comprehensive electronic system capable of dealing with the acquisition and pre-processing of the neutron array is detailed. Among the electronic modules required, we emphasize the front-end analog processing, the digitalization, digital pre-processing and communications firmware, as well as the integration of the GTS (Global Trigger and Synchronization) system, already used successfully in AGATA (Advanced Gamma Tracking Array). The NEDA array will be available for measurements in 2016.