In a recent paper it has been shown that the effective nonlinear constant which is used in a P-Matrix approach to describe third-order intermodulation (IMD3) in surface acoustic wave (SAW) devices can be obtained from finite element (FEM) calculations of a periodic cell using nonlinear tensor data [1]. In this paper we extend this FEM calculation and show that the IMD3 of an infinite periodic array of electrodes on a piezoelectric substrate can be directly simulated in the sagittal plane. This direct approach opens the way for a FEM based simulation of nonlinearities for finite and generalized structures avoiding the simplifications of phenomenological approaches
A reduced-order modelling to predictively simulate the dynamics of piezoelectric structures with geo...
The paper is focused on modeling and simulation of surface acoustic wave devices using finite elemen...
A set of finite elements (FEs) is formulated to analyze wave propagation through inhomogeneous mater...
Nonlinearity can give rise to intermodulation distortions in surface acoustic wave (SAW) devices ope...
Increasing power density causes increased self-generation of harmonics and intermodulation. As this ...
In this work a set of nonlinear coupled COM equations at interacting frequencies is derived on the b...
International audienceThis paper proposes a new numerical coupled Finite Element Method/Boundary Int...
Nonlinearity distortion measurements and accurate modeling techniques for surface acoustic wave (SAW...
Surface acoustic wave devices apart from being small, rugged and reliable can also be used as wirele...
International audienceThe development of new surface acoustic wave devices exhibiting complicated el...
Understanding the mechanism of nonlinearity in SAW/BAW devices is growing up in importance because t...
Surface Acoustic Wave (SAW) devices are key components in RF and IF stages of many electronic system...
The coupling of stress and strain fields to electric fields present in anisotropic piezoelectric cry...
The motivation of this work is to analyze the in-band intermodulation distortion (IMD) occurring in ...
International audienceThe demand for high frequency surface acoustic wave devices for modern telecom...
A reduced-order modelling to predictively simulate the dynamics of piezoelectric structures with geo...
The paper is focused on modeling and simulation of surface acoustic wave devices using finite elemen...
A set of finite elements (FEs) is formulated to analyze wave propagation through inhomogeneous mater...
Nonlinearity can give rise to intermodulation distortions in surface acoustic wave (SAW) devices ope...
Increasing power density causes increased self-generation of harmonics and intermodulation. As this ...
In this work a set of nonlinear coupled COM equations at interacting frequencies is derived on the b...
International audienceThis paper proposes a new numerical coupled Finite Element Method/Boundary Int...
Nonlinearity distortion measurements and accurate modeling techniques for surface acoustic wave (SAW...
Surface acoustic wave devices apart from being small, rugged and reliable can also be used as wirele...
International audienceThe development of new surface acoustic wave devices exhibiting complicated el...
Understanding the mechanism of nonlinearity in SAW/BAW devices is growing up in importance because t...
Surface Acoustic Wave (SAW) devices are key components in RF and IF stages of many electronic system...
The coupling of stress and strain fields to electric fields present in anisotropic piezoelectric cry...
The motivation of this work is to analyze the in-band intermodulation distortion (IMD) occurring in ...
International audienceThe demand for high frequency surface acoustic wave devices for modern telecom...
A reduced-order modelling to predictively simulate the dynamics of piezoelectric structures with geo...
The paper is focused on modeling and simulation of surface acoustic wave devices using finite elemen...
A set of finite elements (FEs) is formulated to analyze wave propagation through inhomogeneous mater...