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Development of an Estimation Instrument of Acoustic Lens Properties for Medical Ultrasound Transducers

Overview
Journal J Healthc Eng
Specialty Biomedical Engineering
Date 2018 Feb 22
PMID 29464102
Citations 8
Authors
Hojong Choi
Jongseon Johnson Jeong
Jungsuk Kim
Affiliations
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Abstract

In medical ultrasound transducers, the transmission mode (pass-through) approach has been used to estimate the characteristics of the acoustic lens. However, it is difficult to measure the acoustic lens properties with high precision because of human, systemic, or mechanical measurement errors. In this paper, we propose a low-cost estimation instrument for acoustic lens properties connected with a customized database. In the instrument, three-axis and one-axis transmitting and material fixtures accurately align the transmitting and receiving transducers separately. Through the developed instrument, we obtained a precise standard deviation of the attenuation coefficient and velocity of the acoustic lens material of 0.05 dB/cm and 2.62 m/s, respectively. Additionally, the simultaneous alignment between the fixtures is controllable with developed programs, thus generating very accurate information of the acoustic lens about the testing ultrasound transducer. In our instrument, the database could support users in managing the result data efficiently. User programs developed using LabVIEW provide the capability to obtain precise values of the attenuation coefficient and velocity, which represent the fundamental material characteristics of the acoustic lens of the medical ultrasound transducers. The developed review program of the customized database can also search the acoustic lens information and store the experimental results.

Citing Articles

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Choi H Technol Health Care. 2022; 30(S1):513-520.

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Development of a low-cost six-axis alignment instrument for flexible 2D and 3D ultrasonic probes.

Kim J, Kim K, Choi H Technol Health Care. 2021; 29(S1):77-84.

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Structural Health Monitoring Using Ultrasonic Guided-Waves and the Degree of Health Index.

Cantero-Chinchilla S, Aranguren G, Royo J, Chiachio M, Etxaniz J, Calvo-Echenique A Sensors (Basel). 2021; 21(3).

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