Characterization of the Beam-Spread Function for Underwater Wireless Optical Communications Links

Optical links are currently being considered for high-bandwidth underwater communications at short ranges (<100 m). To predict the performance of these links, a firm understanding of how the inherent optical properties of water affect the encoded optical signal is needed. Of particular interest is the impact of scattering due to particulates. Typically, the link loss is computed using the beam attenuation coefficient, which describes the attenuation of nonscattered light due to absorption and scattering. This approach is insufficient, as it neglects the contribution of scattered light to the total received signal. Given the dynamic nature of underwater platforms, as well as the dynamic nature of the environment itself, knowledge of the angular dependence of forward-scattered light is imperative for determining pointing and tracking requirements as well as overall signal to noise. In this work, the theory necessary to describe spatial spreading of an optical beam in the presence of scattering agents underwater is reviewed. This theory is then applied to a performance prediction model that is validated via laboratory experiments. Finally, the model is used to study the impact of spatial spreading on an underwater optical link.

[1]  J. McLean,et al.  Beam spread function with time dispersion. , 1998, Applied optics.

[2]  L. Stotts,et al.  Closed form expression for optical pulse broadening in multiple-scattering media. , 1978, Applied optics.

[3]  Willard H. Wells,et al.  Loss of Resolution in Water as a Result of Multiple Small-Angle Scattering , 1969 .

[4]  F. Hanson,et al.  High bandwidth underwater optical communication. , 2008, Applied optics.

[5]  L. Freitag,et al.  High rate acoustic link for underwater video transmission , 2004, Oceans 2003. Celebrating the Past ... Teaming Toward the Future (IEEE Cat. No.03CH37492).

[6]  Seibert Q. Duntley,et al.  Underwater Lighting by Submerged Lasers and Incandescent Sources , 1971 .

[7]  A. Seeger,et al.  THEORY OF SMALL ANGLE SCATTERING OF X RADIATION AND NEUTRONS BY INTERNAL POTENTIALS IN SOLID BODIES, ESPECIALLY BY DISPLACEMENT , 1959 .

[8]  G J Hall,et al.  Moments of multiple scattering. , 1995, Applied optics.

[9]  Jacob R. Longacre,et al.  Underwater propagation of high-data-rate laser communications pulses , 1992, Optics & Photonics.

[10]  Alan Laux,et al.  The a, b, c s of oceanographic lidar predictions: a significant step toward closing the loop between theory and experiment , 2002 .

[11]  Milica Stojanovic,et al.  Recent advances in high-speed underwater acoustic communications , 1996 .

[12]  J W McLean,et al.  Limits of small angle scattering theory. , 1987, Applied optics.

[13]  Lee Freitag,et al.  High-rate acoustic communications for ocean observatories-performance testing over a 3000 m vertical path , 2000, OCEANS 2000 MTS/IEEE Conference and Exhibition. Conference Proceedings (Cat. No.00CH37158).

[14]  Kevin Barraclough,et al.  I and i , 2001, BMJ : British Medical Journal.

[15]  T. J. Petzold Volume Scattering Functions for Selected Ocean Waters , 1972 .

[16]  B. Cochenour,et al.  Effects of Multiple Scattering on the Implementation of an Underwater Wireless Optical Communications Link , 2006, OCEANS 2006.

[17]  B. Cochenour,et al.  Phase Coherent Digital Communications for Wireless Optical Links in Turbid Underwater Environments , 2007, OCEANS 2007.

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

[19]  J. Jaffe,et al.  Monte Carlo modeling of underwater-image formation: validity of the linear and small-angle approximations. , 1995, Applied optics.

[20]  M. Stojanovic,et al.  Underwater acoustic networks , 2000, IEEE Journal of Oceanic Engineering.

[21]  Eleonora P. Zege,et al.  Image Transfer Through a Scattering Medium , 1991 .

[22]  D. Arnush,et al.  Underwater Light-Beam Propagation in the Small-Angle-Scattering Approximation , 1972 .