Acoustic Calibration for the KM3NeT Pre-Production Module

TL;DR

This paper discusses the development and testing of a custom acoustic calibration system for KM3NeT's neutrino detection units, aiming to improve sensor positioning and explore additional deep-sea acoustic applications.

Contribution

It introduces a novel acoustic sensor design with integrated piezoelectric elements and preamplifiers, tailored for KM3NeT's specific requirements and tested within the PPM framework.

Findings

Successful testing of integrated acoustic sensors in the PPM

Potential extension of acoustic systems to particle detection and environmental monitoring

Enhanced positioning accuracy for KM3NeT detection units

Abstract

The proposed large scale Cherenkov neutrino telescope KM3NeT will carry photo-sensors on flexible structures, the detection units. The Mediterranean Sea, where KM3NeT will be installed, constitutes a highly dynamic environment in which the detection units are constantly in motion. Thus it is necessary to monitor the exact sensor positions continuously to achieve the desired resolution for the neutrino telescope. A common way to perform this monitoring is the use of acoustic positioning systems with emitters and receivers based on the piezoelectric effect. The acoustic receivers are attached to detection units whereas the emitters are located at known positions on the sea floor. There are complete commercial systems for this application with sufficient precision. But these systems are limited in the use of their data and inefficient as they were designed to perform only this single task. Several working groups in the KM3NeT consortium are cooperating to custom-design a positioning system for the specific requirements of KM3NeT. Most of the studied solutions hold the possibility to extend the application area from positioning to additional tasks like acoustic particle detection or monitoring of the deep-sea acoustic environment. The KM3NeT Pre-Production Module (PPM) is a test system to verify the correct operation and interoperability of the major involved hardware and software components developed for KM3NeT. In the context of the PPM, alternative designs of acoustic sensors including small piezoelectric elements equipped with preamplifiers inside the same housing as the optical sensors will be tested. These will be described in this article.