An analysis of high power IGBT switching under cascade active voltage control

Author

Wang, Y. ; Bryant, A.T. ; Palmer, P.R. ; Finney, S.J. ; Abu-Khaizaran, M. ; Li, G.

Author_Institution

Cambridge Univ., UK

Volume

2

fYear

2005

fDate

2-6 Oct. 2005

Firstpage

806

Abstract

A new gate drive solution, cascade active voltage control (cascade AVC), employs classic feedback control methods with an inner loop controlling the IGBT gate voltage and an outer loop controlling the collector voltage simultaneously. They make the switching performance less dependent on the IGBT itself. Feedback control of IGBTs in the active region does not necessarily slow the switching, but introduces stability issues. A detailed stability analysis provides a sensible perspective to judge the system stability and justify the controller design, through considering major operating points and determining corresponding IGBT parameters. Experiments on high power IGBTs including a 4500 V device show that cascade AVC offers improved performance and is easier to design than the original AVC.

Keywords

control system synthesis; feedback; insulated gate bipolar transistors; stability; switching; voltage control; 4500 V; active voltage control; cascade active voltage control; collector voltage control; feedback control methods; gate voltage control; high power IGBT switching; stability analysis; Automatic voltage control; Delay; Diodes; Feedback control; Feedback loop; Insulated gate bipolar transistors; Stability analysis; Stress; Switching circuits; Voltage control;

fLanguage

English

Publisher

ieee

Conference_Titel

Industry Applications Conference, 2005. Fourtieth IAS Annual Meeting. Conference Record of the 2005

ISSN

0197-2618

Print_ISBN

0-7803-9208-6

Type

conf

DOI

10.1109/IAS.2005.1518426

Filename

1518426