Simulation of an Underwater Acoustic Communication Channel Characterized by Wind-Generated Surface Waves and Bubbles
conference paper
Sea surface scattering by wind-generated waves and bubbles is regarded to be the main non-platform related cause of
the time variability of shallow acoustic communication channels. Simulations for predicting the quality of acoustic communication links in such channels thus require adequate modeling of these dynamic sea-surface effects. It is known that, for frequencies in the range 1-4 kHz, the main effect of bubbles on sea surface reflection loss is due to refraction, which can be modeled with a modified sound-speed profile accounting for the bubble void fraction in the surface layer. The bubble cloud then acts as an acoustic lens, enhancing the rough-surface scattering by the resulting upward refraction. It is recently shown that, for frequencies in the range 4-8 kHz, bubble extinction also provides a significant contribution to the surface loss, including both the effects of bubble scattering and absorption. As this is the frequency band adopted in the EDA-RACUN project, in which the reported research has been conducted, both bubble refraction and extinction effects should be modeled for acoustic channel simulations in RACUN. These model-based channel simulations are performed by applying a ray-tracer, together with a toolbox for generation of rough sea-surface evolutions. The total simulation framework, called IRSIM, seems to provide realistic results for stationary communication nodes.
the time variability of shallow acoustic communication channels. Simulations for predicting the quality of acoustic communication links in such channels thus require adequate modeling of these dynamic sea-surface effects. It is known that, for frequencies in the range 1-4 kHz, the main effect of bubbles on sea surface reflection loss is due to refraction, which can be modeled with a modified sound-speed profile accounting for the bubble void fraction in the surface layer. The bubble cloud then acts as an acoustic lens, enhancing the rough-surface scattering by the resulting upward refraction. It is recently shown that, for frequencies in the range 4-8 kHz, bubble extinction also provides a significant contribution to the surface loss, including both the effects of bubble scattering and absorption. As this is the frequency band adopted in the EDA-RACUN project, in which the reported research has been conducted, both bubble refraction and extinction effects should be modeled for acoustic channel simulations in RACUN. These model-based channel simulations are performed by applying a ray-tracer, together with a toolbox for generation of rough sea-surface evolutions. The total simulation framework, called IRSIM, seems to provide realistic results for stationary communication nodes.
TNO Identifier
464303
Source title
Underwater Communications: Channel Modelling & Validation - UComms 2012, 12-14 September 2012, Sestri Levante, Italy