📝 SummarXiv

Abstract

The escalating development of oceanic applications like underwater surveillance and mineral exploration, is motivating real-time wireless backhaul of the considerable observation data. Such prospects can be hardly realized by the narrowband acoustic approach. Alternatively, optical wireless communication (OWC) has emerged as a promising solution for maritime and underwater applications due to its great potential for broadband underwater transmission. However, the implementations of water-air OWC can be rather challenging, especially when penetrating the fluctuating interface, where the direction of refracted signals changes dynamically, causing severe beam misalignment with airborne stations. This has necessitated real-time transceiver alignment adaptable to the sophisticated oceanic environment, which has yet to be addressed. Against this background, this paper establishes a mathematical channel model for water-air optical wireless transmission across the fluctuating sea surface. Based on the model, we propose a vision-based beam tracking algorithm that leverages artificial intelligence (AI) methods for dynamic channel prediction. The proposed algorithm integrates a convolutional neural network (CNN) with bi-directional long short-term memory (Bi-LSTM), which further incorporates the attention mechanism to effectively extract critical spatio-temporal features from the vision data. The numerical simulation results show that the proposed algorithm can outperform its classical counterparts in maintaining receiving signal strength and supressing the vision noises, which demonstrates its robustness against the the harsh conditions of water-air OWC systems.