Author_Institution :
Naval Res. Lab., Washington, DC, USA
Abstract :
A new coherent reverberation model developed at the Naval Research Laboratory, Washington, DC, and the Supreme Allied Commander Atlantic Undersea Research Centre, La Spezia, Italy, is exercised in the 17-750-Hz band to estimate the degree of non-Rayleighness of shallow-water reverberation envelopes as a function of waveguide multipath, system bandwidth, directivity, and frequency. Findings suggest that reverberation from diffuse, but non-Gaussian, scatterer distributions is significantly more Rayleigh for multipath environments than for equivalent environments excited by a single or small number of modes or for broadside receiver array processing that extracts narrow angles of reception. These findings suggest that the problem of non-Rayleigh reverberation in shallow-water waveguides can be ameliorated through the use of tuned ensonification and reception schemes, which retain high probabilities of detection while reducing the associated probability of false alarm.
Keywords :
acoustic wave scattering; acoustic waveguides; reverberation; statistical analysis; underwater acoustic propagation; 17 to 750 Hz; acoustic scattering; broad-band bottom reverberation predictions; broadside receiver array processing; coherent reverberation model; detection probability; diffuse scatterer distribution; ensonification scheme; false alarm probability; multipath environments; nonGaussian scatterer distribution; nonRayleigh reverberation; nonRayleighness; reception angles; reception scheme; shallow-water reverberation envelopes; shallow-water waveguides; statistical analysis; system bandwidth; system directivity; system frequency; waveguide multipath; Acoustic scattering; Frequency estimation; Predictive models; Probability; Rayleigh scattering; Reverberation; Scattering parameters; Shape; Sonar measurements; Statistics; Acoustic scattering; statistics;
