Underwater Node Localization using Optoacoustic Signals

TL;DR

This paper introduces a novel underwater node localization method using optoacoustic signals, enabling accurate positioning without surface anchors, thus simplifying deployment and enhancing security in underwater networks.

Contribution

The paper proposes a new optoacoustic-based localization technique for underwater nodes that eliminates the need for anchor nodes or gateways, improving deployment simplicity and security.

Findings

Achieves comparable accuracy to traditional methods

Successfully generates isotropic acoustic signals experimentally

Effective for both static and dynamic underwater nodes

Abstract

Localization of underwater networks is important in many military and civil applications. Because GPS receivers do not work below the water surface, traditional localization methods form a relative topology of underwater nodes (UWNs) and utilize either anchor nodes or floating gateways with dual transceivers in order to determine global coordinates. However, these methods introduce logistical complications and security risks in deploying the anchor and/or surface gateways. This paper tackles such an issue by proposing new localization techniques which can remotely localize UWNs using optoacoustic signals. In our approach, GPS coordinates are transmitted from air to the UWN via creating an underwater temporary isotropic acoustic transmitter with the optoacoustic process. We analyze the process of controlling the shape and size of the plasma to create the isotropic acoustic transmitter and experimentally validate the generation of isotropic acoustic signals. Then two methods of localization are proposed for static and dynamic UWNs. Finally, the simulation results with experimental values show the effectiveness of our approach. Comparing to the traditional techniques, our approach achieves the same accuracy without using any surface or underwater anchor nodes.