A Causal Model for Linear RF Systems Developed From Frequency-Domain Measured Data

Marissa Condon; Rossen Ivanov; Conor Brennan

doi:10.1109/TCSII.2005.849019

A Causal Model for Linear RF Systems Developed From Frequency-Domain Measured Data

Marissa Condon, Rossen Ivanov, Conor Brennan

Research output: Contribution to journal › Article › peer-review

Abstract

With the ever-growing complexity of interconnect networks, models developed from measured data or data from 3-D electromagnetic simulators are increasingly becoming essential. It is to this end that the current contribution is directed. In particular, it focuses on the development of a model via a Fourier series expansion (FSE) approach. Its primary advantage is that the response in the time domain can be explicitly obtained in a simple form for an arbitrary input using only a set of FSE coefficients. Also, it guarantees causality without requiring a numerical implementation of a Hilbert transform. The end result is a causal and stable time-domain representation of a system that may subsequently be used in a time-domain simulator such as SPICE.

Original language	English
Pages (from-to)	457-460
Number of pages	4
Journal	IEEE Transactions on Circuits and Systems II: Express Briefs
Volume	52
Issue number	8
DOIs	https://doi.org/10.1109/TCSII.2005.849019
Publication status	Published - Aug 2005
Externally published	Yes

Keywords

Fourier series expansion (FSE)
high-speed inter-connect
time-domain simulation

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10.1109/TCSII.2005.849019

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abstract = "With the ever-growing complexity of interconnect networks, models developed from measured data or data from 3-D electromagnetic simulators are increasingly becoming essential. It is to this end that the current contribution is directed. In particular, it focuses on the development of a model via a Fourier series expansion (FSE) approach. Its primary advantage is that the response in the time domain can be explicitly obtained in a simple form for an arbitrary input using only a set of FSE coefficients. Also, it guarantees causality without requiring a numerical implementation of a Hilbert transform. The end result is a causal and stable time-domain representation of a system that may subsequently be used in a time-domain simulator such as SPICE.",

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AU - Brennan, Conor

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N2 - With the ever-growing complexity of interconnect networks, models developed from measured data or data from 3-D electromagnetic simulators are increasingly becoming essential. It is to this end that the current contribution is directed. In particular, it focuses on the development of a model via a Fourier series expansion (FSE) approach. Its primary advantage is that the response in the time domain can be explicitly obtained in a simple form for an arbitrary input using only a set of FSE coefficients. Also, it guarantees causality without requiring a numerical implementation of a Hilbert transform. The end result is a causal and stable time-domain representation of a system that may subsequently be used in a time-domain simulator such as SPICE.

AB - With the ever-growing complexity of interconnect networks, models developed from measured data or data from 3-D electromagnetic simulators are increasingly becoming essential. It is to this end that the current contribution is directed. In particular, it focuses on the development of a model via a Fourier series expansion (FSE) approach. Its primary advantage is that the response in the time domain can be explicitly obtained in a simple form for an arbitrary input using only a set of FSE coefficients. Also, it guarantees causality without requiring a numerical implementation of a Hilbert transform. The end result is a causal and stable time-domain representation of a system that may subsequently be used in a time-domain simulator such as SPICE.

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A Causal Model for Linear RF Systems Developed From Frequency-Domain Measured Data

Abstract

Keywords

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