This paper reports the results of an effort of developing a 50 MHz annular array which incorporates a fine grain lead titanate as the piezoelectric material. The array achieves a better sensitivity than a comparable PVDF annular array and demonstrates low lateral coupling for reduced cross-talk. Using resonance techniques, the lead titanate has been fully characterized. The ceramic shows a clamped permittivity (/spl epsiv//sub 33//sup s///spl epsiv//sub 0/) equal to 180, a thickness coupling k/sub t/, of 0.49 and a planar coupling, k/sub p/, of 0.08. This material was fabricated into an annular array with an overall diameter of 5 mm and six equal-area elements. Separation of the elements was achieved using laser micromachining. Utilizing the waveforms from one-dimensional modeling, intensity field calculations predicted a maximum -6 dB lateral beamwidth of 160 /spl mu/m over a six focal-zone region covering a 10 mm depth. Application of a triangular electrical apodization scheme across the elements resulted in a reduction in grating lobe amplitude below -26 dB.
[1]
Ieee Standards Board.
IEEE Standard on Piezoelectricity
,
1996
.
[2]
Ahmad Safari,et al.
Effect of Rare‐Earth Additives on Electromechanical Properties of Modified Lead Titanate Ceramics
,
1993
.
[3]
K. Shung,et al.
Single crystal PZN/PT-polymer composites for ultrasound transducer applications
,
2000,
IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.
[4]
Timothy A. Ritter,et al.
High-frequency single-element and annular array transducers incorporating PVDF
,
2000,
Medical Imaging.
[5]
G. R. Lockwood,et al.
Laser micromachined high frequency ultrasonic arrays
,
1999,
1999 IEEE Ultrasonics Symposium. Proceedings. International Symposium (Cat. No.99CH37027).