W. Steichen scite author profile

W. Steichen

5Publications

125Citation Statements Received

46Citation Statements Given

How they've been cited

237

121

How they cite others

Affiliations

Thales (France), Technicolor (France), Temex (Czechia)

Publications

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A mixed finite element/boundary element approach to simulate complex guided elastic wave periodic transducers

Ballandras

Lardat²,

Wilm

et al. 2009

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International audienceThe development of new surface acoustic wave devices exhibiting complicated electrode patterns or layered excitation transducers has been favored by an intense innovative activity in this area. For instance, devices exhibiting interdigital transducers covered by piezoelectric or dielectric layers have been fabricated and tested, but the design of such structures requires simulation tools capable to accurately take into account the actual shape of the wave guide elements. A modeling approach able to address complicated surface acoustic wave periodic structures (defined in the saggital plane) exhibiting any geometry then has been developed and implemented. It is based on the combination of a finite element analysis and a boundary element method. A first validation of the computation is reported by comparison with standard surface wave devices. Surface transverse wave resonators covered by amorphous silica have been built and consequently used for theory/experiment assessment. Also the case of recessed electrodes has been considered. The proposed model offers large opportunities for modeling any two-dimensional periodic elastic wave guide

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Finite-element analysis of periodic piezoelectric transducers

Ballandras

Wilm

Edoa

et al. 2003

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The need for optimized acoustic transducers for the development of high-quality imaging probes requires efficient simulation tools providing reliable descriptions of the behavior of real devices. The purpose of this work is the implementation of a finite-element model for the simulation of periodic transducer arrays. By using the assumption of harmonic excitation, the harmonic admittance of the studied structure can be derived. It is then shown how the mutual admittance is deduced from this feature, allowing one to estimate the amount of cross-talk effects for a given periodic transducer. Computation results are reported for standard linear acoustic probes, 2-2 ͑one-dimensional periodic͒ and 1-3 ͑two-dimensional periodic͒ piezocomposite materials. In the case of 2-2 connectivity composites, a comparison between nonperiodic and periodic computations of the mutual admittance is conducted, from which the minimum number of periods for which periodic computations can be trustfully considered can be estimated.

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Simulations of surface acoustic wave devices built on stratified media using a mixed finite element/boundary integral formulation

Ballandras

Reinhardt

Laude

et al. 2004

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Tunable Solidly Mounted Thin Film Bulk Acoustic Resonators Based on Ba$_{x}{{\hbox{Sr}}_{1-x}}{\hbox{TiO}}_{3}$ Films

Berge

Vorobiev

Steichen³

et al. 2007

IEEE Microw. Wireless Compon. Lett.

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Study of PZT coated membrane structures for micromachined ultrasonic transducers [medical imaging]

Muralt

Schmitt

Ledermann

et al. 2001

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W. Steichen

A mixed finite element/boundary element approach to simulate complex guided elastic wave periodic transducers

Finite-element analysis of periodic piezoelectric transducers

Simulations of surface acoustic wave devices built on stratified media using a mixed finite element/boundary integral formulation

Tunable Solidly Mounted Thin Film Bulk Acoustic Resonators Based on Ba$_{x}{{\hbox{Sr}}_{1-x}}{\hbox{TiO}}_{3}$ Films

Study of PZT coated membrane structures for micromachined ultrasonic transducers [medical imaging]

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