Grid size adapted multistep methods for high Q oscillators

Hans Georg Brachtendorf; Kai Bittner

doi:10.1109/TCAD.2013.2269800

Grid size adapted multistep methods for high Q oscillators

Hans Georg Brachtendorf, Kai Bittner

Research Center Hagenberg

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

8 Zitate (Scopus)

Abstract

The numerical calculation of the limit cycle of oscillators with resonators exhibiting a high-quality factor Q such as quartz crystals is a difficult task in the time domain. Time domain integration formulas, when not carefully selected, introduce numerical damping that leads to erroneous limit cycles or spurious oscillations. A novel class of adaptive multistep integration formulas based on finite difference (FD) schemes is derived, which circumvent the aforementioned problems. The results are compared with the well-known harmonic balance (HB) technique. Moreover, the range of absolute stability is derived for these methods. The resulting discretized system by FD methods is sparser than that of HB and, therefore, easier to solve and easier to implement.

Originalsprache	Englisch
Aufsatznummer	6634587
Seiten (von - bis)	1682-1693
Seitenumfang	12
Fachzeitschrift	IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems
Jahrgang	32
Ausgabenummer	11
DOIs	https://doi.org/10.1109/TCAD.2013.2269800
Publikationsstatus	Veröffentlicht - 2013

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abstract = "The numerical calculation of the limit cycle of oscillators with resonators exhibiting a high-quality factor Q such as quartz crystals is a difficult task in the time domain. Time domain integration formulas, when not carefully selected, introduce numerical damping that leads to erroneous limit cycles or spurious oscillations. A novel class of adaptive multistep integration formulas based on finite difference (FD) schemes is derived, which circumvent the aforementioned problems. The results are compared with the well-known harmonic balance (HB) technique. Moreover, the range of absolute stability is derived for these methods. The resulting discretized system by FD methods is sparser than that of HB and, therefore, easier to solve and easier to implement.",

keywords = "High Q oscillators, modified backward differentiation formulas (BDF), numerical damping, numerical integration methods",

author = "Brachtendorf, {Hans Georg} and Kai Bittner",

year = "2013",

doi = "10.1109/TCAD.2013.2269800",

language = "English",

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AU - Bittner, Kai

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N2 - The numerical calculation of the limit cycle of oscillators with resonators exhibiting a high-quality factor Q such as quartz crystals is a difficult task in the time domain. Time domain integration formulas, when not carefully selected, introduce numerical damping that leads to erroneous limit cycles or spurious oscillations. A novel class of adaptive multistep integration formulas based on finite difference (FD) schemes is derived, which circumvent the aforementioned problems. The results are compared with the well-known harmonic balance (HB) technique. Moreover, the range of absolute stability is derived for these methods. The resulting discretized system by FD methods is sparser than that of HB and, therefore, easier to solve and easier to implement.

AB - The numerical calculation of the limit cycle of oscillators with resonators exhibiting a high-quality factor Q such as quartz crystals is a difficult task in the time domain. Time domain integration formulas, when not carefully selected, introduce numerical damping that leads to erroneous limit cycles or spurious oscillations. A novel class of adaptive multistep integration formulas based on finite difference (FD) schemes is derived, which circumvent the aforementioned problems. The results are compared with the well-known harmonic balance (HB) technique. Moreover, the range of absolute stability is derived for these methods. The resulting discretized system by FD methods is sparser than that of HB and, therefore, easier to solve and easier to implement.

KW - High Q oscillators

KW - modified backward differentiation formulas (BDF)

KW - numerical damping

KW - numerical integration methods

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JO - IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems

JF - IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems

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Grid size adapted multistep methods for high Q oscillators

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