Today research interests in underwater (UW) communication and navigation technologies are steadily growing. However, the design of robust UW communication and navigation systems demands a deep knowledge of the transmission medium. Acoustic UW (AUW) communication is widely used due to the good propagation characteristics of sound waves in water compared to electromagnetic waves that are highly attenuated. Besides its advantage - the low attenuation compared to electromagnetic waves - AUW communication suffers from multipath propagation, severe Doppler spread due to the low propagation speed of sound, and shadow zones, to name some of the most challenging effects. Evaluation of new communication devices under realistic conditions in sea trials is expensive and time-consuming. Therefore, a simulator modeling the AUW communication channel accurately is a valuable tool for development and evaluation of AUW communication devices. In this paper an Acoustic Underwater Channel and Network Simulator is proposed that uses ray tracing to model the AUW channel. It uses channel impulse responses (CIRs) generated by the BELLHOP ray tracing model to simulate multipath propagation. These CIRs for static constellations of receiver and transmitter are post-processed to be in agreement with the mobility of transmitters and receivers. Thereby, Doppler spread is introduced into the channel model. An empirical noise model is used to superimpose received signals with noise. Different modulation schemes can be evaluated using this AUW channel model in laboratory before expensive sea trials are conducted. In this paper a frequency hopping and an OFDM implementation are realized besides the channel model. Multiple mobile transmitters and receivers can be considered to simulate UW networks.
[1]
Zhu Fanglai.
Modeling and Simulation on Underwater Acoustic Communication Channel
,
2013
.
[2]
C. Clay,et al.
Fundamentals of Acoustical Oceanography
,
1997
.
[3]
Michele Zorzi,et al.
World ocean simulation system (WOSS): a simulation tool for underwater networks with realistic propagation modeling
,
2009,
WUWNet.
[4]
Walter Munk,et al.
Sound channel in an exponentially stratified ocean, with application to SOFAR
,
1974
.
[5]
Grant Pusey,et al.
Development of a simple underwater acoustic channel simulator for analysis and prediction of horizontal data telemetry.
,
2009
.
[6]
Sumit Roy,et al.
Rate-range for an FH-FSK acoustic modem
,
2007,
Underwater Networks.
[7]
Milica Stojanovic,et al.
Underwater Acoustic Communications and Networking: Recent Advances and Future Challenges
,
2008
.
[8]
M. Porter,et al.
Gaussian beam tracing for computing ocean acoustic fields
,
1987
.
[9]
G. Loubet,et al.
Underwater acoustic channel simulations for communication
,
1994,
Proceedings of OCEANS'94.
[10]
P. Etter.
Underwater Acoustic Modelling and Simulation
,
2003
.
[11]
Milica Stojanovic,et al.
On the relationship between capacity and distance in an underwater acoustic communication channel
,
2007,
MOCO.