Abstract
Abstract. To increase the robustness and functionality of piezoceramic ultrasonic sensors, e.g. for flow, material concentration or non-destructive testing, their development is often supported by computer simulations. The results of such finite-element-based simulations are dependent on correct simulation parameters, especially the material data set of the modelled piezoceramic. In recent years several well-known methods for estimation of such parameters have been developed that require knowledge of the sensitivity of a measured behaviour of the material with respect to the parameter set. One such measurable quantity is the electrical impedance of the ceramic. Previous studies for radially symmetric sensors with holohedral electrode setups have shown that the impedance shows little or no sensitivity to certain parameters and simulations reflect this behaviour making parameter estimation difficult. In this paper we have used simulations with special ring-shaped electrode geometry and non-uniform electrical excitation in order to find electrode geometries, with which the computed impedance displays a higher sensitivity to the changes in the parameter set. We find that many such electrode geometries exist in simulations and formulate an optimisation problem to find the local maxima of the sensitivities. Such configurations can be used to conduct experiments and solve the parameter estimation problem more efficiently.
Highlights
In this paper we have used simulations with special ring-shaped electrode geometry and non-uniform electrical excitation in order to find electrode geometries, with which the computed impedance displays a higher sensitivity to the changes in the parameter set
We find that many such electrode geometries exist in simulations and formulate an optimisation problem to find the local maxima of the sensitivities
We have made the experience that this configuration has exceptionally good properties with regard to optimisation as opposed to other geometries tested
Summary
Piezoelectric effect is the physical phenomenon discovered by Pierre and Jacques Curie in 1880 that is exhibited by several crystalline and synthetic ceramic materials. Depending on the application at hand, the full knowledge of the material data set can be crucial to the whole process: for a circular disk with full width electrodes on the top and bottom (see Fig. 1) there is no shear movement; e15 is of no importance Unlike such a disk, in the case of a shear wave transducer the knowledge of e15 is crucial. Analytical and numerical modelling of piezoelectricity and the resulting computer simulations (Kocbach, 2000; Unverzagt et al, 2013) have enabled more efficient design and construction of transducers in recent years Such numerical modelling requires the precise knowledge of the parameters of the material under analysis. We formulate an optimisation problem to find a locally optimal electrode geometry that maximises the sensitivity and show that many such local optima occur
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