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Author Inaba, Y. ♦ Cense, S. ♦ Bachir, T.O. ♦ Yamashita, H. ♦ Dufour, C.
Source IEEE Xplore Digital Library
Content type Text
Publisher Institute of Electrical and Electronics Engineers, Inc. (IEEE)
File Format PDF
Copyright Year ©2011
Language English
Subject Domain (in DDC) Natural sciences & mathematics ♦ Physics ♦ Electricity & electronics ♦ Technology ♦ Engineering & allied operations ♦ Applied physics
Subject Keyword Insulated gate bipolar transistors ♦ FPGA models ♦ Motor drives ♦ Inductance ♦ Hybrid Electric Vehicle (HEV) ♦ Real-time simulation ♦ PMSM motor drive ♦ Inverters ♦ Circuit faults ♦ Mathematical model ♦ Field programmable gate arrays
Abstract This paper presents a FPGA-based virtual motor drive system featuring two Permanent Magnet Synchronous Machine (PMSM) drives made with two-level IGBT/GTO inverters model with full fault capability. The inverters are implemented on the FPGA with a nodal solver, using floating point arithmetic, and support individual component faults, like a single IGBT open fault, as well as other non-standard modes, like cases with no IGBT gate signals and natural rectification. The motor model can be either linear d-q models or Finite Element Analysis models from JMAG-RT. The virtual motor drives are implemented on a Virtex-6 FPGA card and have a total latency near 1μs from the IGBT gate signal capture at Digital Inputs to motor currents at Analog Outputs and are therefore well adapted for HIL tests with high-speed machine with either PWM (up to 100 kHz) or hysteretic current control. Finally, the paper presents experimental accuracy validation made by a TIER-1 supplier for hybrid electric vehicle in Japan.
Description Author affiliation: DENSO Corporation, Corporate ePF Div., Nagoya, Japan (Inaba, Y.; Yamashita, H.) || École Polytechnique de Montréal, Montréal, Qc, Canada (Bachir, T.O.) || Opal-RT Technologies Inc, Montreal Qc, Canada (Cense, S.; Dufour, C.)
ISBN 9781612841670
Educational Role Student ♦ Teacher
Age Range above 22 year
Educational Use Research ♦ Reading
Education Level UG and PG
Learning Resource Type Article
Publisher Date 2011-08-30
Publisher Place United Kingdom
e-ISBN 9789075815146
Size (in Bytes) 1.16 MB
Page Count 10
Starting Page 1
Ending Page 10

Source: IEEE Xplore Digital Library