Finite Element Simulations for Predicting Nonlinear Responses of Layered SAW Systems
- Increasing power density causes increased self-generation of harmonics and intermodulation. As this leads to violations of the strict linearity requirements, especially for carrier aggregation (CA), the nonlinearity must be considered in the design process of RF devices. This raises the demand of accurate simulation models. Linear and nonlinear P-Matrix/COM models are used during the design due toIncreasing power density causes increased self-generation of harmonics and intermodulation. As this leads to violations of the strict linearity requirements, especially for carrier aggregation (CA), the nonlinearity must be considered in the design process of RF devices. This raises the demand of accurate simulation models. Linear and nonlinear P-Matrix/COM models are used during the design due to their fast simulation times and accurate results. However, the finite element method (FEM) is useful to get a deeper insight in the device's nonlinearities, as the total field distributions can be visualized. The FE method requires complete sets of material tensors, which are unknown for most relevant materials in nonlinear micro-acoustics. In this work, we perform nonlinear FEM simulations, which allow the calculation of nonlinear field distributions of a lithium tantalate based layered SAW system up to third order. We aim at achieving good correspondence to measured data and determine the contributions of each material layer to the nonlinear signals. Therefore, we use approximations circumventing the issue of limited higher order tensor data. Experimental data for the third order nonlinearity is shown to validate the presented approach.…
Document Type: | Conference Proceeding |
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Conference Type: | Konferenzartikel |
Zitierlink: | https://opus.hs-offenburg.de/5379 | Bibliografische Angaben |
Title (English): | Finite Element Simulations for Predicting Nonlinear Responses of Layered SAW Systems |
Conference: | IEEE International Ultrasonics Symposium (IUS), 11-16 Sept. 2021, Xi'an, China |
Author: | Thomas Forster, Vikrant Chauhan, Markus Mayer, Elena MayerStaff Member, Andreas MayerStaff MemberGND, Thomas Ebner, Karl Wagner, Amelie Hagelauer |
Year of Publication: | 2021 |
Publisher: | IEEE |
Page Number: | 4 |
First Page: | 1 |
Last Page: | 4 |
Parent Title (English): | IEEE IUS 2021 Symposium Proceedings |
ISBN: | 978-1-6654-0355-9 (elektronisch) |
ISBN: | 978-1-6654-4777-5 (Print on Demand) |
ISSN: | 1948-5727 (elektronisch) |
ISSN: | 1948-5719 (Print on Demand) |
DOI: | https://doi.org/10.1109/IUS52206.2021.9593732 |
Language: | English | Inhaltliche Informationen |
Institutes: | Fakultät Wirtschaft (W) |
Institutes: | Bibliografie | Formale Angaben |
Open Access: | Closed Access |
Licence (German): | Urheberrechtlich geschützt |