Abstract
A piezoelectric ultrasonic transducer (PUT) is widely used in nondestructive testing, medical imaging, and particle manipulation, etc., and the performance of the PUT determines its functional performance and effectiveness in these applications. The optimization design method of a PUT is very important for the fabrication of a high-performance PUT. In this paper, traditional and efficient optimization design methods for a PUT are presented. The traditional optimization design methods are mainly based on an analytical model, an equivalent circuit model, or a finite element model and the design parameters are adjusted by a trial-and-error method, which relies on the experience of experts and has a relatively low efficiency. Recently, by combining intelligent optimization algorithms, efficient optimization design methods for a PUT have been developed based on a traditional model or a data-driven model, which can effectively improve the design efficiency of a PUT and reduce its development cycle and cost. The advantages and disadvantages of the presented methods are compared and discussed. Finally, the optimization design methods for PUT are concluded, and their future perspectives are discussed.
Highlights
Sound waves are a form of energy transmission in the mechanical vibration state of an object
Traditional optimization design methods for a piezoelectric ultrasonic transducer (PUT) are developed based on an analytical model, an ECM, or a finite element model (FEM), and the design parameters are determined by using a trial-and-error method, which is inefficient and depends on the knowledge of experts
Produced from [47]); (B) mathematical model for a concave annular high intensity focused ultrasonic transducer and its sonic transducer and its finite element model; (C) optimization design finite element model; (C) optimization design for a piezoelectric ultrasonic transducer using the for a piezoelectric ultrasonic transducer using the particle swarm optimization algorithm
Summary
, Linwei Wang, Xingjun Luo, Chunlong Fei, Di Li * , Guangbao Shan * and Yintang Yang Citation: Chen, D.; Wang, L.; Luo, X.; Abstract: A piezoelectric ultrasonic transducer (PUT) is widely used in nondestructive testing, medical imaging, and particle manipulation, etc., and the performance of the PUT determines its functional performance and effectiveness in these applications. The optimization design method of a PUT is very important for the fabrication of a high-performance PUT. In this paper, traditional and efficient optimization design methods for a PUT are presented. The traditional optimization design methods are mainly based on an analytical model, an equivalent circuit model, or a finite element model and the design parameters are adjusted by a trial-and-error method, which relies on the experience of experts and has a relatively low efficiency. Recently, by combining intelligent optimization algorithms, efficient optimization design methods for a PUT have been developed based on a traditional model or a data-driven model, which can effectively improve the design efficiency of a PUT and reduce its development cycle and cost. The advantages and disadvantages of the presented methods are compared and discussed. Finally, the optimization design methods for PUT are concluded, and their future perspectives are discussed. Fei, C.; Li, D.; Shan, G.; Yang, Y. Keywords: piezoelectric ultrasonic transducer; optimization design; finite element model; datadriven model; intelligent optimization algorithm
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