Mitigating Deadtime in Distributed Optical Arrays: A Liveness-Aware Trigger Approach for High-Energy Neutrino Detection
Thammarat Yawisit, Pittaya Pannil
TL;DR
This paper introduces a liveness-aware trigger architecture for distributed optical arrays in neutrino detection, improving efficiency and robustness during detector deadtime by preserving signal continuity and phase information.
Contribution
It proposes a recursive IIR-based observable that maintains signal integrity during non-liveness intervals, enabling high-efficiency event detection under elevated deadtime conditions.
Findings
Maintains high event recovery efficiency during elevated deadtime.
Yields up to 100x improvement in effective signal-to-noise ratio.
Demonstrates robustness against saturation and non-ideal conditions.
Abstract
Large-scale neutrino observatories operate under unavoidable detector deadtime arising from photomultiplier saturation, digitizer limits, and front-end readout constraints. Conventional coincidence-based trigger logic implicitly assumes continuous sensor availability and therefore suffers systematic efficiency loss when channels become temporarily non-live. This work presents the design of a liveness-aware trigger architecture targeting low-latency FPGA deployment in distributed optical arrays. We introduce a recursive Infinite Impulse Response (IIR) update law implemented as a fully synthesizable pipeline that constructs a continuity-preserving effective observable at each sensor node. Rather than collapsing during non-liveness intervals, the observable decays smoothly while retaining phase and amplitude information relevant for network-level coherence estimation. By explicitly…
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Taxonomy
TopicsRadiation Detection and Scintillator Technologies · Neutrino Physics Research · Astrophysics and Cosmic Phenomena