Directivity and Frequency-Dependent Effective Sensitive Element Size of Needle Hydrophones: Predictions From Four Theoretical Forms Compared With Measurements

Wear, Keith A.; Baker, Christian; Miloro, Piero

doi:10.1109/tuffc.2018.2855967

Cited by 35 publications

(35 citation statements)

References 39 publications

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“…Over the range from 2.25 to 15 MHz, the average magnitudes of differences between the effective and nominal sensitive element radii were 59 ± 49% (RB), 10 ± 5% (RP), 46 ± 38% (UB), and 71 ± 19% (SB). The decline of a eff with frequency is consistent with reported measurements for needle [35, 39, 45], fiber optic [45], and membrane [42] hydrophones. (Recall that k is directly proportional to frequency.…”

Section: Resultssupporting

confidence: 90%

“…Alternative methods for directivity measurement include a pulsed near-field method [37], a harmonic-based approach [35, 38] a time-delay-spectrometry (TDS) based method [39], and a method based on using a photoacoustic source consisting of a blackened planar surface illuminated by a laser [40, 41].…”

Section: Methodsmentioning

confidence: 99%

“…However, Wear et al . subsequently demonstrated good agreement between the RP model and experimental measurements of sensitivity of needle and reflectance-based fiber optic hydrophones (12% ± 3% root-mean-square difference in normalized sensitivity [29]) and directivity of needle hydrophones (7% ± 5% accuracy in measurement of geometrical sensitive element radius [35]).…”

Section: Introductionmentioning

confidence: 99%

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Directivity and Frequency-Dependent Effective Sensitive Element Size of a Reflectance-Based Fiber-Optic Hydrophone: Predictions From Theoretical Models Compared With Measurements

Wear

Howard²

2018

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

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The goal of this work was to measure directivity of a reflectance-based fiber-optic hydrophone at multiple frequencies and to compare it to four theoretical models: Rigid Baffle (RB), Rigid Piston (RP), Unbaffled (UB), and Soft Baffle (SB). The fiber had a nominal 105 μm diameter core and a 125 μm overall diameter (core + cladding). Directivity measurements were performed at 2.25, 3.5, 5, 7.5, 10, and 15 MHz from ±90° in two orthogonal planes. Effective hydrophone sensitive element radius was estimated by least-squares fitting the four models to directivity measurements using the sensitive element radius as an adjustable parameter. Over the range from 2.25 to 15 MHz, the average magnitudes of differences between the effective and nominal sensitive element radii were 59 ± 49% (RB), 10 ± 5% (RP), 46 ± 38% (UB), and 71 ± 19% (SB). Therefore, directivity of a reflectance-based fiber-optic hydrophone may be best estimated by the RP model.

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Section: Resultssupporting

confidence: 90%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Directivity and Frequency-Dependent Effective Sensitive Element Size of a Reflectance-Based Fiber-Optic Hydrophone: Predictions From Theoretical Models Compared With Measurements

Wear

Howard²

2018

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

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“…The numerator and denominator of the ratio should be calculated based on the hydrophone effective sensitive element radius a eff (f), which is a function of frequency and can differ from the geometrical radius, a g [50]. Functional forms for a eff (f) have been reported for needle and fiber optic hydrophones [50,67,68]. The spatial averaging filter may be written as [50]…”

Section: B Spatial Averaging Filtermentioning

confidence: 99%

“…A formula for the frequency-dependent effective sensitive element size [50], which is required for (5), can be derived from a rigid piston model [73,74] that has been previously validated for sensitivity [75,76] and directivity [67] of needle hydrophones and sensitivity [76] and directivity [68] of fiber optic hydrophones.…”

Section: B Spatial Averaging Filtermentioning

confidence: 99%

Correction for Spatial Averaging Artifacts in Hydrophone Measurements of High-Intensity Therapeutic Ultrasound: An Inverse Filter Approach

Wear

Howard²

2019

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

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High-intensity therapeutic ultrasound (HITU) pressure is often measured using a hydrophone. HITU pressure waves typically contain multiple harmonics due to nonlinear propagation. As harmonic frequency increases, harmonic beam width decreases. For sufficiently high harmonic frequency, beam width may become comparable to the hydrophone effective sensitive element diameter, resulting in signal reduction due to spatial averaging. An analytic formula for a hydrophone spatial averaging filter for beams with Gaussian harmonic radial profiles was tested on HITU pressure signals generated by three transducers (1.45 MHz, F/1; 1.53 MHz, F/1.5; 3.91 MHz, F/1) with focal pressures up to 48 MPa. The HITU signals were measured using fiber-optic and needle hydrophones (nominal geometrical sensitive element diameters: 100 μm and 400 μm). Harmonic radial profiles were measured with transverse scans in the focal plane using the fiberoptic hydrophone. Harmonic radial profiles were accurately approximated by Gaussian functions with root-mean-square (RMS) differences between transverse scans and Gaussian fits less than 9% for frequencies up to approximately 50 MHz. The Gaussian harmonic beam width parameter σ n varied with harmonic number n according to a power law, σ n = σ 1 /n q where 0.5 < q < 0.6. RMS differences between experimental and theoretical spatial averaging filters were 11% ± 1% (1.45 MHz), 8% ± 1% (1.53 MHz), and 4% ± 1% (3.91 MHz). For the two more highly focused (F/1) transducers, the effect of spatial averaging was to underestimate peak compressional pressure (pcp), peak rarefactional pressure (prp), and pulse intensity integral (pii) by (mean ± standard deviation) (pcp: 4.9% ± 0.5%, prp: 0.4% ± 0.2% pii: 2.9% ± 1.0%) and (pcp: 28.3% ± 9.6% prp: 6.0% ± 2.4% pii: 24.3% ± 6.7%) for the 100 μm and 400 μm diameter hydrophones respectively. These errors can be suppressed by application of the inverse spatial averaging filter.

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The calibration methods of hydrophones for underwater environmental sound measurements or biomedical ultrasound measurements: A review

Qin,

Lu,

et al. 2025

Measurement

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Directivity and Frequency-Dependent Effective Sensitive Element Size of Needle Hydrophones: Predictions From Four Theoretical Forms Compared With Measurements

Cited by 35 publications

References 39 publications

Directivity and Frequency-Dependent Effective Sensitive Element Size of a Reflectance-Based Fiber-Optic Hydrophone: Predictions From Theoretical Models Compared With Measurements

Directivity and Frequency-Dependent Effective Sensitive Element Size of a Reflectance-Based Fiber-Optic Hydrophone: Predictions From Theoretical Models Compared With Measurements

Correction for Spatial Averaging Artifacts in Hydrophone Measurements of High-Intensity Therapeutic Ultrasound: An Inverse Filter Approach

The calibration methods of hydrophones for underwater environmental sound measurements or biomedical ultrasound measurements: A review

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