HAWC Timing Calibration

TL;DR

This paper details the design and initial performance results of a laser-based timing calibration system for the HAWC gamma-ray and cosmic-ray detector, aiming to achieve high angular resolution.

Contribution

It introduces a novel optical fiber calibration system for HAWC's PMTs, improving timing accuracy for better event reconstruction.

Findings

Calibration system uses ~1 ns laser pulses for precise timing.

Optical fibers enable calibration of individual PMTs.

System designed for continuous, remote operation.

Abstract

The High-Altitude Water Cherenkov (HAWC) Experiment is a second-generation highsensitivity gamma-ray and cosmic-ray detector that builds on the experience and technology of the Milagro observatory. Like Milagro, HAWC utilizes the water Cherenkov technique to measure extensive air showers. Instead of a pond filled with water (as in Milagro) an array of closely packed water tanks is used. The event direction will be reconstructed using the times when the PMTs in each tank are triggered. Therefore, the timing calibration will be crucial for reaching an angular resolution as low as 0.25 degrees.We propose to use a laser calibration system, patterned after the calibration system in Milagro. Like Milagro, the HAWC optical calibration system will use ~1 ns laser light pulses. Unlike Milagro, the PMTs are optically isolated and require their own optical fiber calibration. For HAWC the laser light pulses will be directed through a series of optical fan-outs and fibers to illuminate the PMTs in approximately one half of the tanks on any given pulse. Time slewing corrections will be made using neutraldensity filters to control the light intensity over 4 orders of magnitude. This system is envisioned to run continuously at a low rate and will be controlled remotely. In this paper, we present the design of the calibration system and first measurements of its performance.