Online Modeling and Prediction of the Large-Scale Temporal Variation in Underwater Acoustic Communication Channels

Influenced by environmental conditions, underwater acoustic communication channels exhibit dynamics on various time scales. The channel dynamics within a short transmission duration have been extensively studied in existing research. In this paper, we investigate online modeling and prediction of slowly-varying channel parameters in a long term, by exploiting their inherent temporal correlation and correlation with water environmental conditions. Examples of those parameters include the locally-averaged channel properties within a transmission, such as the average channel-gain-to-noise-power ratio, the fast fading statistics, the average delay spread, and the average Doppler spread. Adopting a data-driven perspective, this paper models the temporal evolution of a slowly-varying channel parameter of interest as the summation of a time-invariant component, a time-varying process that can be explicitly represented by available environmental parameters, and a Markov latent process that describes the contribution from unknown or unmeasurable physical mechanisms. An algorithm is developed to recursively estimate the unknown model parameters and predict the channel parameter of interest, based on the sequentially collected channel measurements and environmental parameters in real time. We further extend the above model and the recursive algorithm to channels that exhibit periodic (a.k.a. seasonal) dynamics, by introducing a multiplicative seasonal autoregressive process to model the seasonal correlation. The proposed models and algorithms are evaluated via extensive simulations and data sets from two shallow-water experiments. The experimental results reveal that the average channel-gain-to-noise-power ratio, the fast fading statistics, and the average delay spread can be well predicted.

[1]  Konstantinos Pelekanakis,et al.  Channel variability measurements in an underwater acoustic network , 2014, 2014 Underwater Communications and Networking (UComms).

[2]  M. Stojanovic,et al.  Statistical Characterization and Computationally Efficient Modeling of a Class of Underwater Acoustic Communication Channels , 2013, IEEE Journal of Oceanic Engineering.

[3]  Manuel P. Malumbres,et al.  Statistical Modeling of Large-Scale Signal Path Loss in Underwater Acoustic Networks , 2013, Sensors.

[4]  Emrecan Demirors,et al.  A High-Rate Software-Defined Underwater Acoustic Modem With Real-Time Adaptation Capabilities , 2018, IEEE Access.

[5]  Shengli Zhou,et al.  Sparse channel estimation for multicarrier underwater acoustic communication: From subspace methods to compressed sensing , 2009, OCEANS 2009-EUROPE.

[6]  A.B. Baggeroer,et al.  The state of the art in underwater acoustic telemetry , 2000, IEEE Journal of Oceanic Engineering.

[7]  D. E. Weston,et al.  Wind effects in shallow‐water acoustic transmission , 1989 .

[8]  J. Nystuen,et al.  Prediction of underwater sound levels from rain and wind. , 2005, The Journal of the Acoustical Society of America.

[9]  P Casari,et al.  Performance study of variable-rate modulation for underwater communications based on experimental data , 2010, OCEANS 2010 MTS/IEEE SEATTLE.

[10]  H. Hashemi,et al.  Statistical modeling and simulation of the RMS delay spread of indoor radio propagation channels , 1994 .

[11]  W. Hodgkiss,et al.  Impact of ocean variability on coherent underwater acoustic communications during the Kauai experiment (KauaiEx) , 2008 .

[12]  W. Hodgkiss,et al.  Effects of tidally driven temperature fluctuations on shallow-water acoustic communications at 18 kHz , 2000, IEEE Journal of Oceanic Engineering.

[13]  J. Rissanen,et al.  Modeling By Shortest Data Description* , 1978, Autom..

[14]  Parastoo Qarabaqi,et al.  Modeling the large scale transmission loss in underwater acoustic channels , 2011, 2011 49th Annual Allerton Conference on Communication, Control, and Computing (Allerton).

[15]  Thia Kirubarajan,et al.  Estimation with Applications to Tracking and Navigation: Theory, Algorithms and Software , 2001 .

[16]  Sergio M. Jesus,et al.  Linking Acoustic Communications and Network Performance: Integration and Experimentation of an Underwater Acoustic Network , 2013, IEEE Journal of Oceanic Engineering.

[17]  Milica Stojanovic,et al.  Underwater Acoustic Communications and Networking: Recent Advances and Future Challenges , 2008 .

[18]  Michele Zorzi,et al.  A Study on the Wide-Sense Stationarity of the Underwater Acoustic Channel for Non-coherent Communication Systems , 2011, EW.

[19]  Nasser M. Nasrabadi,et al.  Pattern Recognition and Machine Learning , 2006, Technometrics.

[20]  Zhaohui Wang,et al.  Modeling and prediction of large-scale temporal variation in underwater acoustic channels , 2016, OCEANS 2016 - Shanghai.

[21]  Chaofeng Wang,et al.  Adaptive transmission scheduling in time-varying underwater acoustic channels , 2015, OCEANS 2015 - MTS/IEEE Washington.

[22]  Paul A. van Walree,et al.  Ultrawideband Underwater Acoustic Communication Channels , 2013, IEEE Journal of Oceanic Engineering.

[23]  Michael A. Ainslie,et al.  A simplified formula for viscous and chemical absorption in sea water , 1998 .

[24]  Mandar Chitre,et al.  A high-frequency warm shallow water acoustic communications channel model and measurements. , 2007, The Journal of the Acoustical Society of America.

[25]  Paul van Walree,et al.  Propagation and Scattering Effects in Underwater Acoustic Communication Channels , 2013 .