The concept of endoscopic ultrasound (EUS) has been introduced to non-destructive testing for the inspection of tubular structure. However, the fixed normal focusing beam of the present EUS transducers obstructs imaging flexibility and limits the robustness of the inspection, particularly for planar reflectors. To address this challenge, a two-dimensional circular array (2-D CA) designed for three-dimensional focusing is developed in this paper. A prototype 2-D CA transducer is fabricated and validated, which is demonstrated has a central frequency of 10.10 MHz and an average pulse duration of no more than 344 ns. An independent-dual-focusing beamforming scheme is further proposed, providing delay laws in two orthogonal directions. The acoustic field simulation results confirm that the 2-D CA is capable of achieving focusing in any direction, thereby enhancing the flexibility of EUS imaging. The imaging performance of the 2-D CA is evaluated through the immersion EUS inspection of a stainless-steel tube specimen. All the quasi-planar reflectors, including ring grooves with narrow-width, small-diameter flat bottom holes, and longitudinal grooves, are successfully detected in the 2-D CA imaging results. These reflectors could hardly be recognized by the conventional CA with a fixed-normal beam, affirming the superior detection robustness of the 2-D CA. The detection signal-to-noise ratio and error of quantitative characterization of the 2-D CA are 26.12 dB higher and 40.37 % lower than those of conventional CA, respectively. The proposed 2-D CA enables novel and advanced EUS imaging modalities, which have potential applications in both medical imaging and non-destructive testing domains.
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| http://dx.doi.org/10.1109/TUFFC.2024.3509474 | DOI Listing |
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