6533b821fe1ef96bd127b7f5

RESEARCH PRODUCT

A Geometry-Based Underwater Acoustic Channel Model Allowing for Sloped Ocean Bottom Conditions

Rym HicheriNeji YoussefMeisam NaderiMatthias Patzold

subject

010505 oceanographyApplied MathematicsAutocorrelation020206 networking & telecommunicationsGeometry02 engineering and technology01 natural sciencesComputer Science ApplicationsDelay spreadChannel capacity0202 electrical engineering electronic engineering information engineeringElectrical and Electronic EngineeringWidebandUnderwaterPower delay profileGeologyCoherence bandwidthComputer Science::Information Theory0105 earth and related environmental sciencesCommunication channel

description

This paper proposes a new geometry-based channel model for shallow-water ocean environments, in which the ocean bottom can slope gently down/up. The need for developing such an underwater acoustic (UWA) channel model is driven by the fact that the standard assumption of a flat ocean bottom does not hold in many realistic scenarios. Starting from a geometrical model, we develop a stochastic channel model for wideband single-input single-output vehicle-to-vehicle UWA channels using the ray theory assuming smooth ocean surface and bottom. We investigate the effect of the ocean-bottom slope angle on the distribution of the channel envelope, instantaneous channel capacity, temporal autocorrelation function, frequency correlation function, Doppler power spectral density, and the power delay profile. Theoretical and simulation results show that even a relatively small slope angle influences considerably the statistical properties of UWA channels. The validation of the proposed UWA channel model has been performed by fitting its main characteristic quantities (average delay, delay spread, and coherence bandwidth) to measurement data. In comparison with the conventional UWA channel model, which has been developed on the assumption of a flat ocean bottom, it is shown that the proposed UWA channel model enables the modeling of measured channels with higher precision.

yearjournalcountryeditionlanguage
2017-04-01IEEE Transactions on Wireless Communications
https://doi.org/10.1109/twc.2017.2664829