A two-dimensional theory for high-frequency vibrations of piezoelectric crystal plates with or without electrodes

Lee, P. C. Y.; Syngellakis, S.; Hou, Janpu

doi:10.1063/1.338102

Cited by 155 publications

(33 citation statements)

References 12 publications

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“…The boundary conditions at the edges are applied in an average sense as in other plate theories. Higher-order plate theories have also been formulated by Mindlin and Medick, 10 Vlasov, 11 Lo et al, 12 Kant, 13 Reddy, 14 Hanna and Leissa, 15 Lee and Yu, 16 and Lee et al 17 ; this list is by no means complete. Exceptions to the usual expansions of the mechanical displacements and the electric potential as a power series in the thickness coordinate are the works of Soldatos and Watson, 9 Mindlin and Medick, 10 and Lee et al 17 Soldatos and Watson 9 use exponential functions, Mindlin and Medick 10 use Legendre polynomials, and…”

Section: Introduction Bmentioning

confidence: 99%

Higher-Order Piezoelectric Plate Theory Derived from a Three-Dimensional Variational Principle

2002

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A three-dimensional mixed variational principle is used to derive a Kth-order two-dimensional linear theory for an anisotropic homogeneous piezoelectric (PZT) plate. The mechanical displacements, the electric potential, the inplane components of the stress tensor, and the in-plane components of the electric displacement are expressed as a nite series of order K in the thickness coordinate by taking Legendre polynomials as the basis functions. However, the transverse shear stress, the transverse normal stress, and the transverse electric displacement are expressed as a nite series of order (K + 2) in the thickness coordinate. The formulation accounts for the double forces without moments that may change the thickness of the plate. Results obtained by using the plate theory are given for the bending of a cantilever thick plate loaded on the top and the bottom surfaces by uniformly distributed 1) normal tractions and 2) tangential tractions. Results are also computed for the bending of a cantilever thick PZT beam loaded by 1) a uniformly distributed charge density on the top and the bottom surfaces and 2) equal and opposite normal tractions distributed uniformly only on a part of the beam. The seventh-order plate theory captures well the boundary-layer effects near the clamped and the free edges and adjacent to the top and the bottom surfaces of a thick orthotropic cantilever beam with the span to the thickness ratio of two. Also, through-the-thickness variation of the transverse shear and the transverse normal stresses agree well with those computed from the analytical solution of the three-dimensional elasticity equations. The governing partial differential equations are second order, so that Lagrange basis functions can be used to solve the problem by the nite element method.

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Section: Introduction Bmentioning

confidence: 99%

Higher-Order Piezoelectric Plate Theory Derived from a Three-Dimensional Variational Principle

2002

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“…In most cases approximate two-dimensional (2D) plate equations [5][6][7] which are much simpler than the three-dimensional equations of elasticity or piezoelectricity are used. There exist systematic theoretical results from the 2D plate equations for TSh modes with in-plane variation in one direction only, i.e., in the direction parallel to the TSh particle velocity.…”

Section: Introductionmentioning

confidence: 99%

Analysis of a monolithic crystal plate acoustic wave filter

Liu

Yang

2011

Ultrasonics

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a b s t r a c tWe study thickness-shear and thickness-twist vibrations of a finite, monolithic, AT-cut quartz plate crystal filter with two pairs of electrodes. The equations of anisotropic elasticity are used with the omission of the small elastic constant c 56 . An analytical solution is obtained using Fourier series from which the resonant frequencies, mode shapes, and the vibration confinement due to the electrode inertia are calculated and examined.

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“…Equation (19) satisfies Eqs. (3) and (6). To apply the boundary conditions at the plate top and bottom in Eq.…”

Section: Fourier Series Solutionmentioning

confidence: 99%

“…Two approaches are often used. One is to develop approximate, twodimensional (2-D) plate equations [4][5][6] to simplify the problems so that theoretical analyses are possible. The other is to use numerical techniques like the finite element method.…”

Section: Introductionmentioning

confidence: 99%

Thickness-shear vibration of a rectangular quartz plate with partial electrodes

Yang

Kosinski

et al. 2013

Acta Mechanica Solida Sinica

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We study free vibration of a thickness-shear mode crystal resonator of AT-cut quartz. The resonator is a rectangular plate partially and symmetrically electroded at the center with rectangular electrodes. A single-mode, three-dimensional equation governing the thickness-shear displacement is used. A Fourier series solution is obtained. Numerical results calculated from the series show that there exist trapped thickness-shear modes whose vibration is mainly under the electrodes and decays rapidly outside the electrodes. The effects of the electrode size and thickness on the trapped modes are examined.

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A two-dimensional theory for high-frequency vibrations of piezoelectric crystal plates with or without electrodes

Cited by 155 publications

References 12 publications

Higher-Order Piezoelectric Plate Theory Derived from a Three-Dimensional Variational Principle

Higher-Order Piezoelectric Plate Theory Derived from a Three-Dimensional Variational Principle

Analysis of a monolithic crystal plate acoustic wave filter

Thickness-shear vibration of a rectangular quartz plate with partial electrodes

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