• DocumentCode
    1036164
  • Title

    Simulation of non-Rayleigh reverberation and clutter

  • Author

    Abraham, Douglas A. ; Lyons, Anthony P.

  • Author_Institution
    Appl. Res. Lab., Pennsylvania State Univ., State College, PA, USA
  • Volume
    29
  • Issue
    2
  • fYear
    2004
  • fDate
    4/1/2004 12:00:00 AM
  • Firstpage
    347
  • Lastpage
    362
  • Abstract
    The simulation of active sonar reverberation time series has traditionally been done using either a computationally intensive point-scatterer model or a Rayleigh-distributed reverberation-envelope model with a time-varying power level. Although adequate in scenarios where reverberation arises from a multitude of scatterers, the Rayleigh model is not representative of the target-like non-Rayleigh reverberation or clutter commonly observed with modern high-resolution sonar systems operating in shallow-water environments. In this paper, techniques for simulating non-Rayleigh reverberation are developed within the context of the finite-number-of-scatterers representation of K-distributed reverberation, which allows control of the reverberation-envelope statistics as a function of system (beamwidth and bandwidth) and environmental (scatterer density and size) parameters. To avoid the high computational effort of the point-scatterer model, reverberation is simulated at the output of the matched filter and is generated using efficient approximate methods for forming K-distributed random variables. Finite impulse response filters are used to introduce the effects of multipath propagation and the shape of the reverberation power spectrum, the latter of which requires the development of a prewarping of the K distribution parameters to control the reverberation-envelope statistics. The simulation methods presented in this paper will be useful in the testing and evaluation of active sonar signal processing algorithms, as well as for simulation-based research on the effects of the sonar system and environment on the reverberation-envelope probability density function.
  • Keywords
    acoustic wave propagation; acoustic wave scattering; clutter; matched filters; reverberation; sonar signal processing; K distribution parameters; K-distributed random variables; K-distributed reverberation; Rayleigh model; Rayleigh-distributed reverberation-envelope model; active sonar reverberation; bandwidth; beamwidth; clutter; environmental parameter; finite impulse response filters; finite-number-of-scatterers representation; matched filter; multipath propagation; nonRayleigh reverberation; point-scatterer model; probability density function; reverberation power spectrum; reverberation-envelope statistics; scatterer density; scatterer size; shallow-water environments; signal processing algorithms; sonar systems; time series analysis; time-varying power level; Bandwidth; Computational modeling; Context modeling; Power system modeling; Rayleigh scattering; Reverberation; Shape control; Size control; Sonar; Statistics; $K$ distribution; Clutter; multipath; non-Rayleigh; reverberation; simulation; sonar;
  • fLanguage
    English
  • Journal_Title
    Oceanic Engineering, IEEE Journal of
  • Publisher
    ieee
  • ISSN
    0364-9059
  • Type

    jour

  • DOI
    10.1109/JOE.2004.828202
  • Filename
    1315724