Underwater acoustic communications

In recent years, underwater acoustic (UWA) communications have received much attention as their applications are beginning to shift from military towards commercial. UWA communications are made difficult by the combined effect of multipath propagation and high temporal and spatial variability of the channel conditions. Until recently, the design of communication systems has mostly relied on the use of noncoherent modulation techniques. However, to achieve high data rates on the severely bandlimited UWA channels, bandwidth-efficient modulation techniques must be considered, together with array processing for exploitation of spatial multipath diversity. The new generation of underwater communication systems employing phase-coherent modulation techniques will achieve at least a ten fold increase in data throughput. The communication scenario in which the modern UWA systems will operate is that of an underwater network consisting of stationary and mobile nodes. Current research focuses on the development of efficient signal processing algorithms, multiuser communications in the presence of interference, and design of efficient modulation and coding schemes.<<ETX>>

[1]  J. A. Catipovic,et al.  Design and performance analysis of a Digital Acoustic Telemetry System for the short range underwater channel , 1984 .

[2]  David J. Brady,et al.  Reduced-complexity RLS estimation for shallow-water channels , 1994, Proceedings of IEEE Symposium on Autonomous Underwater Vehicle Technology (AUV'94).

[3]  J. A. Catipovic,et al.  Performance limitations in underwater acoustic telemetry , 1990 .

[4]  J. A. Catipovic,et al.  The design and performance of a compact underwater acoustic network node , 1994, Proceedings of OCEANS'94.

[6]  J. A. Catipovic,et al.  Adaptive multiuser detection for underwater acoustical channels , 1994 .

[7]  A. Baggeroer,et al.  Acoustic telemetry - An overview , 1984, IEEE Journal of Oceanic Engineering.

[8]  J. A. Catipovic,et al.  Phase-coherent digital communications for underwater acoustic channels , 1994 .

[9]  J. A. Catipovic,et al.  Performance of sequential decoding of convolutional codes over fully fading ocean acoustic channels , 1990 .

[10]  Jeffrey H. Fischer,et al.  A High Data Rate, Underwater Acoustic Data-communications Transceiver , 1992, OCEANS 92 Proceedings@m_Mastering the Oceans Through Technology.

[11]  T. Birdsall Acoustic telemetry for ocean acoustic tomography , 1984, IEEE Journal of Oceanic Engineering.

[12]  S. Flatté Sound transmission through a fluctuating ocean , 1977 .

[13]  A. Kaya,et al.  An Acoustic Communication System for Subsea Robot , 1989, Proceedings OCEANS.

[14]  A. Quazi,et al.  Underwater acoustic communications , 1982, IEEE Communications Magazine.

[15]  William A. Kuperman MODELS OF SOUND PROPAGATION IN THE OCEAN , 1985 .

[16]  B. K. Gazey,et al.  Sound transmission through a fluctuating ocean , 1980 .

[17]  J. Proakis,et al.  Adaptive multichannel combining and equalization for underwater acoustic communications , 1993 .

[18]  A. E. Adams,et al.  Sub-sea acoustic remote communications utilising an adaptive receiving beamformer for multipath suppression , 1994, Proceedings of OCEANS'94.

[19]  J. A. Catipovic,et al.  Spatial processing of broadband underwater acoustic communication signals in the presence of co-channel interference , 1994, Proceedings of OCEANS'94.

[20]  J. A. Catipovic,et al.  High data rate acoustic telemetry for moving ROVs in a fading multipath shallow water environment , 1990, Symposium on Autonomous Underwater Vehicle Technology.

[21]  Masanobu Suzuki,et al.  Digital Acoustic Image Transmission System For Deep-sea Research Submersible , 1992, OCEANS 92 Proceedings@m_Mastering the Oceans Through Technology.

[22]  John G. Proakis Coded modulation for digital communications over Rayleigh fading channels , 1991 .

[23]  Arthur B. Baggeroer,et al.  The Heard Island papers: A contribution to global acoustics , 1994 .