This paper presents a FEM analysis of a membrane-based Surface Acoustic Wave(SAW)sensor.The sensor is a 2.45GHz Reflective Delay Line(R-DL)based on Lithium Niobate(LiNbO_(3)).As the wave propagation time is much small...This paper presents a FEM analysis of a membrane-based Surface Acoustic Wave(SAW)sensor.The sensor is a 2.45GHz Reflective Delay Line(R-DL)based on Lithium Niobate(LiNbO_(3)).As the wave propagation time is much smaller than the typical time constant of the phenomena to be monitored(deformation,temperature change etc.),the analysis can be performed in three successive steps.First,a static FEM study of the complete sensor(housing included)is carried out,to compute the temperature,stress and strain fields generated in the sensitive area by the measured parameters(pressure,temperature,etc.).Then,a dynamic electro-mechanical study of the R-DL is performed.The simulation takes the previously computed fields into account,which makes it possible to compute the sensor sensitivity to the measured parameters.The model takes advantage of the periodicity of the components of the R-DL to compute phenomenological parameters(Coupling-of-Mode parameters),which can later on be used to compute the electrical response of the sensor(step 3).In this paper,we focus on the first two steps.The COM parameters are extracted,under simultaneous thermal and mechanical stresses.Especially,the sensor sensitivity is obtained from the evolution of the velocity,under various stress configurations.展开更多
基金This project has been partly supported by the COMET K1 center ASSIC Austrian Smart Systems Integration Research Center.The COMET‘Competence Centers for Excellent Technologies’program is supported by BMVIT,BMWFW and the federal provinces of Carinthia and Styria.
文摘This paper presents a FEM analysis of a membrane-based Surface Acoustic Wave(SAW)sensor.The sensor is a 2.45GHz Reflective Delay Line(R-DL)based on Lithium Niobate(LiNbO_(3)).As the wave propagation time is much smaller than the typical time constant of the phenomena to be monitored(deformation,temperature change etc.),the analysis can be performed in three successive steps.First,a static FEM study of the complete sensor(housing included)is carried out,to compute the temperature,stress and strain fields generated in the sensitive area by the measured parameters(pressure,temperature,etc.).Then,a dynamic electro-mechanical study of the R-DL is performed.The simulation takes the previously computed fields into account,which makes it possible to compute the sensor sensitivity to the measured parameters.The model takes advantage of the periodicity of the components of the R-DL to compute phenomenological parameters(Coupling-of-Mode parameters),which can later on be used to compute the electrical response of the sensor(step 3).In this paper,we focus on the first two steps.The COM parameters are extracted,under simultaneous thermal and mechanical stresses.Especially,the sensor sensitivity is obtained from the evolution of the velocity,under various stress configurations.
