S. Finette et Rm. Heitmeyer, ANGLE-TIME-FREQUENCY RESOLUTION OF THE NOISE FIELD GENERATED BY WIND-INDUCED BREAKING WAVES, The Journal of the Acoustical Society of America, 99(1), 1996, pp. 209-222
This paper describes a model of the noise field generated by waves bre
aking on the ocean surface and the angle-time-frequency resolution of
that noise field. The model takes into account the discrete space-time
structure of the noise sources and thus differs from models based on
the continuous source sheet assumption. This is done using a stochasti
c model to specify the locations, occurrence times, and radiated noise
waveforms for the individual breaking waves and then computing the no
ise field as the superposition of the noise contributions from those b
reaking waves. The angle-time-frequency resolution of the noise field
is obtained by applying a time-frequency resolution algorithm to the o
utput of a beamformer as a function of the steering angle. To describe
the properties of the 3-D noise resolution, we assume a vertical arra
y in a shallow-water acoustic environment and use recently obtained ex
perimental estimates of the acoustic coverage and the source level and
waveform-duration probability densities to determine the breaking wav
e source model parameters. The examples presented indicate that the br
eaking wave noise is largely confined to two angular sectors, the high
-angle sector looking toward the ocean surface and the sector containi
ng the discrete mode propagation energy. The high-angle noise exhibits
a large temporal variability, characterized by a small number of larg
e broadband bursts, and is only weakly dependent on the acoustic envir
onment. On the other hand, the discrete mode noise shows less temporal
variability, characterized by a larger number of smaller broadband bu
rsts, and is strongly dependent on the acoustic environment. Finally,
the angle-frequency structure of the low-level noise in the downward-l
ooking direction represents an example of imaging the bottom with surf
ace-generated ambient noise and suggests that ambient noise measuremen
ts might be used to estimate sediment thickness. (C) 1996 Acoustical S
ociety of America.