Signal Processing for Pico-second Resolution Timing Measurements

TL;DR

This paper explores signal processing techniques for pico-second resolution timing measurements using advanced photo-detectors and ASIC electronics, emphasizing the importance of understanding signal dynamics to achieve ultra-fast timing accuracy.

Contribution

It compares four signal processing methods through simulation to determine optimal approaches for pico-second timing resolution in large-area photo-detectors.

Findings

Pulse waveform sampling offers superior timing precision.

Multiple-threshold discriminators improve resolution over single-threshold methods.

Understanding detector noise is crucial for achieving pico-second timing accuracy.

Abstract

The development of large-area homogeneous photo-detectors with sub-millimeter path lengths for direct Cherenkov light and for secondary-electrons opens the possibility of large time-of-flight systems for relativistic particles with resolutions in the pico-second range. Modern ASIC techniques allow fast multi-channel front-end electronics capable of sub-pico-second resolution directly integrated with the photo-detectors. However, achieving resolution in the pico-second range requires a precise knowledge of the signal generation process in order to understand the pulse waveform, the signal dynamics, and the noise induced by the detector itself, as well as the noise added by the processing electronics. Using the parameters measured for fast photo-detectors such as micro-channel plates photo-multipliers, we have simulated and compared the time-resolutions for four signal processing techniques: leading edge discriminators, constant fraction discriminators, multiple-threshold discriminators and pulse waveform sampling.