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http://dx.doi.org/10.5657/KFAS.2014.0302

Bandwidth Enhancement of a Broadband Ultrasonic Mosaic Transducer using 48 Tonpilz Transducer Elements with 12 Resonance Frequencies  

Lee, Dae-Jae (Division of Marine Production System Management, Pukyong National University)
Publication Information
Korean Journal of Fisheries and Aquatic Sciences / v.47, no.3, 2014 , pp. 302-312 More about this Journal
Abstract
This article describes the design and performance characteristics of a broadband ultrasonic mosaic transducer. We focus on the improved bandwidth in the high frequency band of a previously designed broadband ultrasonic transducer (Lee et al., 2014). The improvement in the pulse-echo bandwidth was achieved by employing twelve $2{\times}2$ element subarrays, operating at different resonance frequencies, and utilizing the mosaic array concept. We found that the -6 dB and -12 dB bandwidths of the newly developed broadband ultrasonic mosaic transducer, were up to 155% and 170% of the previously designed model, with a quality factor of 1.71 and 1.25, respectively. The averaged TVR (transmitting voltage response), SRT (receiving sensitivity), and FOM (figure of merit) values in a nearly flat transmitting response band, from 45 to 105 kHz providing a -12 dB bandwith of 60 kHz, were 163.3 dB (re $1{\mu}Pa/V$ at 1 m), -192.8 dB (re $1V/{\mu}Pa$), and -30.9 dB, respectively.
Keywords
Broadband ultrasonic transducer; Mosaic array; 48 tonpilz transducer elements; 60 kHz bandwidth; Three-dimensional matrix model;
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Times Cited By KSCI : 4  (Citation Analysis)
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1 Mancic D and Radmanovic M. 2004. Design of ultrasonic transducers by means of the apparent elasticity method. Working and Living Environmental Protection 2, 293-300.
2 Mancic D, Radmanovic M, Petrusic Z and Stancic G. 2008. Influence of ultrasonic transducer acoustic impedances and dimensions on its input electrical impedance. Working and Living Environmental Protection 5, 59-72.
3 Mancic D and Stancic G. 2010. New three-dimensional matrix modes of the ultrasonic sandwich transducers. J Sandwich Struc Mater 12, 63-80.   DOI   ScienceOn
4 Radmanovic M and Mancic D. 2004. Design and modeling of the power ultrasonic transducers. MP Interconsulting, Le Locle, Switzerland, 8-161.
5 Rajapan D. 2002. Performance of a low-frequency, multi-resonant broadband Tonpilz transducer. J Acoust Soc Am 111, 1692-1694.   DOI   ScienceOn
6 Yao Q and Bjorno L. 1997. Broadband Tonpilz underwater acoustic transducers based on multimode optimation. IEEE Trans Ultrason Ferroelect Freq Contr 44, 1060-1066.   DOI   ScienceOn
7 Lee DJ and Shin HI. 2001. Development of a split beam transducer for measuring fish size distribution. Bull Korean Soc Fish Tech 37, 196-213.   과학기술학회마을
8 Kachanov VK, Sokolov IV, Konov MM, Timofeev DV and Sinitsyn AA. 2010. Development of a broadband low-frequency mosaic ultrasonic piezoelectric transducer with a limited aperture. Russian J Nondestr Test 46, 645-650. http://dx.doi.org/10.1134/S1061830910090044.   DOI
9 Kachanov VK, Sokolov IV, Konov MM and Sinitsyn AA. 2011. Comparision of the futures of composit and mosaic piezotransducers for the ultrasonic testing of products with a high attenuation level of ultrasonic signals. Russian J Nondestr Test 47, 532-544. http://dx.doi.org/10.1134/S1061830911080067.   DOI
10 Kara H, Ramesh R, Stevens R and Browen CR. 2003. Porous PZT ceramic for receiving transducers. IEEE Trans Ultrason Ferroelect Freq Contr 50, 289-296.   DOI   ScienceOn
11 Lee DJ and Lee WS. 2010. Design, fabrication and performance characteristics of a 50 kHz Tonpilz type transducer with a half-wavelength diameter. J Kor Soc Fish Tech 46, 173-183. http://dx.doi.org/10.3796/KSFT.2010.46.2.173.   DOI   ScienceOn
12 Lee DJ and Lee WS. 2011. Development of split-beam acoustic transducer for a 50 kHz fish sizing echo sounder. Kor J Fish Aquat Sci 44, 413-422. http://dx.doi.org/10.5657/KFAS. 2011.0413.   과학기술학회마을   DOI   ScienceOn
13 Lee DJ. 2011. Estimation of angular location and directivity compensation of split-beam acoustic transducer for a 50 kHz fish sizing echo sounder. Kor J Fish Aquat Sci 44, 423-430. http://dx.doi.org/10.5657/KFAS. 2011.0423.   과학기술학회마을   DOI   ScienceOn
14 Lee DJ, Kwak MS and Kang HY. 2014. Design and development of the broadband ultrasonic transducer operating over the frequency range of 40 kHz to 75 kHz. Kor J Fish Aquat Sci, In press.   과학기술학회마을   DOI   ScienceOn
15 Lin S. 1994. The three-dimensional equivalent circuit and natural frequencies of rectangular piezoelectric ceramic resonators. J Acoust Soc Am 96, 1620-1626.   DOI   ScienceOn
16 Lin S. 2005. Analysis of the sandwich piezoelectric ultrasonic transducer in coupled vibration. J Acoust Soc Am 117, 653-661.   DOI   ScienceOn
17 Hughes WJ and Zipparo MJ. 1969. Computer modeling of ultrasonic piezoelectric transducers. Technical report TR 96-007, Applied Research Lab, The Pennsylvania State Univ, Pennsylvania, USA, 1-116.
18 Lin S and Hua T. 2008. Study on the sandwich piezoelectric ceramic ultrasonic transducer in thickness vibration. Smart Mater Struct 17, 1-9.
19 Mancic D. and Radmanovic M. 2002. piezoceramic ring loaded on the face: a three-demensional approach. Electro J Tech Acoust 2, 1-7.
20 Hawkins DW and Gough PT. 1996. Multiresonance design of a Tonpilz transducer using the finite element method. IEEE Trans Ultrason Ferroelect Freq Contr 40, 782-789.
21 Hughes WJ. 1998. Transducer, underwater acoustic. Encyclopedia of applied physics 22, 67-84.
22 Ilua A, Carotenuto R and Pappalardo M. 2002. An approximated 3-D model of the Langevin t ransducer and its experimental validation. J Acoust Soc Am 111, 2675-2680.   DOI   ScienceOn
23 Kachanov VK and Sokolov IV. 2007. Requirement for choosing the parameters of broadband transducers for testing objects with high damping of ultrasonic signals. Russian J Nondestr Test 43, 743-754. http://dx.doi.org/10.1134/S1061830907110058.   DOI
24 Feng F, Shen J and Den J. 2006. A 2D equivalent circuit of piezelectric ceramic ring for transducer design. Ultrasonics 44, 723-726.   DOI   ScienceOn