Optimal frequency sweep method in multi-rate circuit simulation-Reference-Cited by-同舟云学术

Optimal frequency sweep method in multi-rate circuit simulation

Published:2014-07-01 Issue:4 Volume:33 Page:1189-1197
ISSN:0332-1649
Container-title:COMPEL: The International Journal for Computation and Mathematics in Electrical and Electronic Engineering
language:en
Short-container-title:

Author:

Bittner Kai,Georg Brachtendorf Hans

Abstract

Purpose – Radio-frequency circuits often possess a multi-rate behavior. Slow changing baseband signals and fast oscillating carrier signals often occur in the same circuit. Frequency modulated signals pose a particular challenge. The paper aims to discuss these issues. Design/methodology/approach – The ordinary circuit differential equations are first rewritten by a system of (multi-rate) partial differential equations in order to decouple the different time scales. For an efficient simulation the paper needs an optimal choice of a frequency-dependent parameter. This is achieved by an additional smoothness condition. Findings – By incorporating the smoothness condition into the discretization, the paper obtains a non-linear system of equations complemented by a minimization constraint. This problem is solved by a modified Newton method, which needs only little extra computational effort. The method is tested on a phase locked loop with a frequency modulated input signal. Originality/value – A new optimal frequency sweep method was introduced, which will permit a very efficient simulation of multi-rate circuits.

Publisher

Emerald

Subject

Applied Mathematics,Electrical and Electronic Engineering,Computational Theory and Mathematics,Computer Science Applications

Reference13 articles.

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2. Bittner, K. and Dautbegovic, E. (2012b), “Wavelets algorithm for circuit simulation”, Progress in Industrial Mathematics at ECMI 2010, in Günther, M. , Bartel, A. , Brunk, M. , Schöps, S. and Striebel, M. (Eds), Mathematics in Industry, Springer, Berlin, Heidelberg, pp. 5-11.

3. Brachtendorf, H.G. (1994), Simulation des eingeschwungenen Verhaltens elektronischer Schaltungen, Shaker, Aachen.

4. Brachtendorf, H.G. (1997), “On the relation of certain classes of ordinary differential algebraic equations with partial differential algebraic equations”, Technical Report No. 1131G0-971114-19TM, Bell-Laboratories, Murray Hill.

5. Brachtendorf, H.G. (2001), “Theorie und Analyse von autonomen und quasiperiodisch angeregten elektrischen Netzwerken”, Eine algorithmisch orientierte Betrachtung, Universität Bremen, Habilitationsschrift.

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