Calibration sphere for low-frequency parametric sonars

2007

OCEANS 2007 - Europe

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The target strengths of hollow ceramic flotation spheres manufactured by DeepSea Power and Light, Inc., and tested to a pressure equivalent of 12,000 m have been measured as a function of frequency over the bands 10-150 kHz. The spheres are made of alumina, purity 99.9%, with diameter 91.44 ± 0.2 mm, nominal thickness 1.3 mm, mass 140 ± 1 g. The target strength spectra have also been calculated theoretically assuming a mass density of 3.984 g/cm3, longitudinal-and transverse-wave sound speeds of 11000 and 6510 m/s, respectively. Measurements and computations are compared. Potential applications of the sphere as a standard acoustic target are noted.

Section: Introductionmentioning

confidence: 99%

Broadband Ultrasonic Target Strengths of Hollow Ceramic Flotation Spheres

Atkins

Francis

2007

OCEANS 2007 - Europe

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“…Admittedly, the array was virtual, existing in space away from the transducer, as the formation of an exceptionally directional beam at very low frequencies depends on the cumulative effect of the nonlinearity inherent in the medium on the propagating and interacting primary, high-frequency waves. 34 A scheme for quantification of parametric sonar echoes has been developed, 35,36 drawing on a computational model for the difference-frequency nearfield of the parametric sonar, i.e., the nearfield. 37,38 In some underwater geophysical investigations, measurements are inevitably made in the nearfield, for example, with high-frequency sidescan sonars operating at short ranges.…”

Section: B Importance Of the Nearfieldmentioning

confidence: 99%

Discriminating between the nearfield and the farfield of acoustic transducers

The Journal of the Acoustical Society of America

2014

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Measurements of the performance of acoustic transducers, as well as ordinary measurements made with the same, may require discriminating between the farfield, where the field is spherically divergent, and the complementary nearfield, where the field structure is more complicated. The problem is addressed for a planar circular piston projector, with uniform normal velocity distribution, mounted in an infinite planar rigid baffle. The inward-extrapolated farfield pressure amplitude p f is compared with the exact nearfield pressure amplitude p n , modeled by the Rayleigh integral, through the error 20 log jp f /p n j. Three sets of computations are performed for a piston with wavenumber-radius product ka ¼ 10: normalized pressure amplitudes and error versus range at angles corresponding to beam pattern losses of 0, 10, 20, and 30 dB; error versus angle at three ranges, a 2 /k, pa 2 /k, and 10a 2 /k, where k is the wavelength; and range versus angle for each of two inward-bounded errors, 1 and 0.3 dB. By reciprocity, the results apply equally to the case of a baffled circular piston receiver with uniform sensitivity over the active surface. It is proposed that proximity criteria for measurements of fields associated with circular pistons be established by like modeling, and that a quality factor be assigned to measurements on the basis of computed errors.

“…When available, results for the standard-target calibration 42,43 performed during the first cruise 9 will be used in frequency-dependent scaling factors so that the rangecompensated echograms can be expressed in absolute physical units of volume backscattering strength. This will enable measurements made in the mid-frequency sonar band to be compared with echo measurements made at ordinary ultrasonic frequencies, e.g., 18, 38, 120, and 200 kHz, among others.…”

Section: E Future Workmentioning

confidence: 99%

Range compensation for backscattering measurements in the difference-frequency nearfield of a parametric sonar

The Journal of the Acoustical Society of America

2012

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Measurement of acoustic backscattering properties of targets requires removal of the range dependence of echoes. This process is called range compensation. For conventional sonars making measurements in the transducer farfield, the compensation removes effects of geometrical spreading and absorption. For parametric sonars consisting of a parametric acoustic transmitter and a conventional-sonar receiver, two additional range dependences require compensation when making measurements in the nonlinearly generated difference-frequency nearfield: an apparently increasing source level and a changing beamwidth. General expressions are derived for range compensation functions in the difference-frequency nearfield of parametric sonars. These are evaluated numerically for a parametric sonar whose difference-frequency band, effectively 1-6 kHz, is being used to observe Atlantic herring (Clupea harengus) in situ. Range compensation functions for this sonar are compared with corresponding functions for conventional sonars for the cases of single and multiple scatterers. Dependences of these range compensation functions on the parametric sonar transducer shape, size, acoustic power density, and hydrography are investigated. Parametric range compensation functions, when applied with calibration data, will enable difference-frequency echoes to be expressed in physical units of volume backscattering, and backscattering spectra, including fish-swimbladder-resonances, to be analyzed.