Frequency Tuning of Collapse-Mode Capacitive Micromachined Ultrasonic Transducer

•Frequency tuning of CMUT operated in (deep-)collapse mode is experimentally quantified.•The CMUT is operated at bias voltages up to three times higher than the collapse voltage.•Fabricated CMUT operates reliably for single-use imaging catheter application.•Images are constructed based on combinatio...

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Bibliographic Details
Published in:Ultrasonics 2017-02, Vol.74, p.144-152
Main Authors: Pekař, Martin, Dittmer, Wendy U., Mihajlović, Nenad, van Soest, Gijs, de Jong, Nico
Format: Article
Language:English
Subjects:
Capacitive micromachined ultrasonic transducer
CMUT
Collapse mode
Deep-collapse mode
Frequency tuning
Imaging
Intracardiac
Multi-frequency
Ultrasound
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Summary:•Frequency tuning of CMUT operated in (deep-)collapse mode is experimentally quantified.•The CMUT is operated at bias voltages up to three times higher than the collapse voltage.•Fabricated CMUT operates reliably for single-use imaging catheter application.•Images are constructed based on combinations of driving frequency and bias voltage.•Reciprocity measurements indicate the same bias voltage can be used for transmit and receive. The information in an ultrasound image depends on the frequency that is used. In a clinical examination it may therefore be beneficial to generate ultrasound images acquired at multiple frequencies, which is difficult to achieve with conventional transducers. Capacitive micromachined ultrasonic transducers (CMUTs) offer a frequency response that is tunable by the bias voltage. In this study we investigate this frequency tunability for ultrasonic imaging. We characterized a CMUT array operated at bias voltages up to three times higher than the collapse-voltage. All elements of the array were connected to a single transmit and receive channel through a bias circuit. We quantified the transmit-receive and transmit sensitivity as a function of frequency for a range of bias voltages. Impulse response measurements show that the center frequency is modifiable between 8.7MHz and 15.3MHz with an applied bias voltage of −50V to −170V. The maximum transmit sensitivity is 52kPa/V at a center frequency of 9.0MHz with an applied bias voltage of −105V. The −3dB transmit range in center frequency accessible with the variable bias voltage is 6.7–15.5MHz. This study shows that a collapse-mode CMUT can operate efficiently at multiple center frequencies when the driving pulse and the bias voltage are optimized. We demonstrate the usefulness of frequency tuning by comparing images at different optimal combinations of driving frequency and bias voltage, acquired by linearly moving the transducer across a tissue mimicking phantom.
ISSN:0041-624X
1874-9968
DOI:10.1016/j.ultras.2016.10.002