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Recently a new technology of piezoelectric transducers based on PZT thick film has been developed as a response to a call for devices working at higher frequencies suitable for production in large numbers at low cost. Eight PZT thick film based focused transducers with resonant frequency close to 40 MHz were fabricated and experimentally investigated. The PZT thick films were deposited on acoustically engineered ceramic substrates by pad printing. Considering high frequency and nonlinear propagation it has been decided to evaluate the axial pressure field emitted (and reflected by thick metal plate) by each of concave transducer differing in radius of curvature – 11 mm, 12 mm, 15 mm, 16 mm. All transducers were activated using AVTEC AVG-3A-PS transmitter and Ritec diplexer connected directly to Agilent 54641D oscilloscope. As anticipated, in all cases the focal distance was up to 10% closer to the transducer face than the one related to the curvature radius. Axial pressure distributions were also compared to the calculated ones (with the experimentally determined boundary conditions) using the angular spectrum method including nonlinear propagation in water. The computed results are in a very good agreement with the experimental ones. The trans- ducers were excited with Golay coded sequences at 35–40 MHz. Introducing the coded excitation allowed replacing the short-burst transmission at 20 MHz with the same peak amplitude pressure, but with almost double center frequency, resulting in considerably better axial resolution. The thick films exhibited at least 30% bandwidth broadening comparing to the standard PZ 27 transducer, resulting in an increase in matching filtering output by a factor of 1.4–1.5 and finally resulting in a SNR gain of the same order.
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Tom
Strony
945--954
Opis fizyczny
Bibliogr. 7 poz., fot., wykr.
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autor
autor
autor
autor
autor
autor
autor
- Department of Ultrasound Institute of Fundamental Technological Research Polish Academy of Sciences Pawińskiego 5B, 02-106 Warszawa, Poland, anowicki@ippt.gov.pl
Bibliografia
- 1. Christopher P., Parker K. (1991), New approaches to nonlinear diffractive field propagation, J. Acous. Soc. Am., 90, 488-499.
- 2. Kuznetsov V.P. (1970), Equations of nonlinear acoustics, Akust. Zh., 16, 548-553.
- 3. Lewandowski M., Nowicki A. (2008), High frequency coded imaging system with RF software signal processing, IEEE Trans. Ultrason. Ferroelectr. Freq. Control, 55, 8, 1878-1882.
- 4. Nowicki A., Klimonda Z., Lewandowski M., Litniewski J., Lewin P.A., Trots I. (2006), Comparison of sound fields generated by different coded excitations - experimental results, Ultrasonics, 44, 1, 121-129.
- 5. Wójcik J., Nowicki A., Lewin P.A., Bloomfield P.E., Kujawska T., Filipczynski J. (2006), Wave envelopes method for description of nonlinear acoustic wave propagation, Ultrasonics, 44, 3, 310-329.
- 6. Wójcik J., Kujawska T., Nowicki A., Lewin P.A. (2008), Fast prediction of pulsed nonlinear acoustic fields from clinically relevant sources using time-averaged wave envelope approach: Comparison of numerical simulations and experimental results, Ultrasonics (Elsevier), 48, 8, 707-715.
- 7. Wójcik J., Kujawska T., Nowicki A. (2008), Pulsed nonlinear acoustic fields from clinically relevant sources; numerical calculations and experimental results, Archives of Acoustics, 33, 4, 565-572.
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Bibliografia
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bwmeta1.element.baztech-article-BUS8-0020-0058