Classification and synthesis of power gyrators

A. Cid-Pastor; L. Martinez-Salamero; C. Alonso; G. Schweitz; J. Calvente; S. Singer

Classification and synthesis of power gyrators

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Classification and synthesis of power gyrators

Author(s): A. Cid-Pastor ; L. Martinez-Salamero ; C. Alonso ; G. Schweitz ; J. Calvente ; S. Singer
DOI: 10.1049/ip-epa:20050413

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Author(s): A. Cid-Pastor ¹ ; L. Martinez-Salamero ² ; C. Alonso ³ ; G. Schweitz ⁴ ; J. Calvente ² ; S. Singer ⁵
- Affiliations: 1: LAAS-CNRS, France and EDF R&D, Site des Renardières, Moret sur Loing, France
  2: LAAS-CNRS, ETSE-URV, Campus Sescelades, Tarragona, Spain
  3: LAAS-CNRS, Toulouse Cedex 4, Toulouse, France
  4: EDF R&D, Site des Renardières, France
  5: Faculty of Engineering, Tel Aviv University, Tel-Aviv, Israel
Source: Volume 153, Issue 6, November 2006, p. 802 – 808
DOI: 10.1049/ip-epa:20050413 , Print ISSN 1350-2352, Online ISSN 1359-7043

Published

A systematic procedure to synthesise power gyrators for variable switching frequency operation is presented. Based on the gyrator equations, topological constraints are first established and two types of gyrators, i.e. G and R, are defined. A boost converter with an output filter and the Čuk converter are shown to have the unconditionally stable characteristics of G-gyrators with a controlled input current whereas a buck converter with an input filter and also the Čuk converter are shown to behave as G-gyrators with a controlled output current if damping networks are inserted and certain stability conditions are accomplished. Similarly, a boost converter with an output filter is shown to behave as a power R-gyrator with stable dynamics.

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Classification and synthesis of power gyrators

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