A novel parametric macromodeling technique for electromagnetic structures with propagation delays
- Author
- M. Sgueglia, A. Sorrentino, M. de Magistris, Domenico Spina (UGent) , Dirk Deschrijver (UGent) and Tom Dhaene (UGent)
- Organization
- Abstract
- This work addresses the problem of building accurate and stable parametric macromodels for distributed electronic structures with propagation delays. First, reduced root macromodels are calculated by means of Delayed Vector Fitting technique at estimation points of the design space grid. Then, a suitable interpolation scheme for the delay trends and rational terms is proposed, preserving the model stability over the entire design space. The fundamentals of the identification scheme are discussed, and some insight on basic robustness and accuracy problems is provided. A couple of significant case studies are reported to demonstrate the accuracy and efficiency of the presented technique.
- Keywords
- IBCN
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Citation
Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-8541166
- MLA
- Sgueglia, M., et al. “A Novel Parametric Macromodeling Technique for Electromagnetic Structures with Propagation Delays.” 2017 IEEE 21ST WORKSHOP ON SIGNAL AND POWER INTEGRITY (SPI), 2017.
- APA
- Sgueglia, M., Sorrentino, A., de Magistris, M., Spina, D., Deschrijver, D., & Dhaene, T. (2017). A novel parametric macromodeling technique for electromagnetic structures with propagation delays. 2017 IEEE 21ST WORKSHOP ON SIGNAL AND POWER INTEGRITY (SPI). Presented at the 21st IEEE Workshop on Signal and Power Integrity (SPI), Baveno, ITALY.
- Chicago author-date
- Sgueglia, M., A. Sorrentino, M. de Magistris, Domenico Spina, Dirk Deschrijver, and Tom Dhaene. 2017. “A Novel Parametric Macromodeling Technique for Electromagnetic Structures with Propagation Delays.” In 2017 IEEE 21ST WORKSHOP ON SIGNAL AND POWER INTEGRITY (SPI). May 07-10, 2017.
- Chicago author-date (all authors)
- Sgueglia, M., A. Sorrentino, M. de Magistris, Domenico Spina, Dirk Deschrijver, and Tom Dhaene. 2017. “A Novel Parametric Macromodeling Technique for Electromagnetic Structures with Propagation Delays.” In 2017 IEEE 21ST WORKSHOP ON SIGNAL AND POWER INTEGRITY (SPI). May 07-10, 2017.
- Vancouver
- 1.Sgueglia M, Sorrentino A, de Magistris M, Spina D, Deschrijver D, Dhaene T. A novel parametric macromodeling technique for electromagnetic structures with propagation delays. In: 2017 IEEE 21ST WORKSHOP ON SIGNAL AND POWER INTEGRITY (SPI). May 07-10, 2017; 2017.
- IEEE
- [1]M. Sgueglia, A. Sorrentino, M. de Magistris, D. Spina, D. Deschrijver, and T. Dhaene, “A novel parametric macromodeling technique for electromagnetic structures with propagation delays,” in 2017 IEEE 21ST WORKSHOP ON SIGNAL AND POWER INTEGRITY (SPI), Baveno, ITALY, 2017.
@inproceedings{8541166,
abstract = {{This work addresses the problem of building accurate and stable parametric macromodels for distributed electronic structures with propagation delays. First, reduced root macromodels are calculated by means of Delayed Vector Fitting technique at estimation points of the design space grid. Then, a suitable interpolation scheme for the delay trends and rational terms is proposed, preserving the model stability over the entire design space. The fundamentals of the identification scheme are discussed, and some insight on basic robustness and accuracy problems is provided. A couple of significant case studies are reported to demonstrate the accuracy and efficiency of the presented technique.}},
author = {{Sgueglia, M. and Sorrentino, A. and de Magistris, M. and Spina, Domenico and Deschrijver, Dirk and Dhaene, Tom}},
booktitle = {{2017 IEEE 21ST WORKSHOP ON SIGNAL AND POWER INTEGRITY (SPI)}},
isbn = {{978-1-5090-5616-3}},
issn = {{2475-9481}},
keywords = {{IBCN}},
language = {{eng}},
location = {{Baveno, ITALY}},
title = {{A novel parametric macromodeling technique for electromagnetic structures with propagation delays}},
year = {{2017}},
}