FPGA-based Real-time HIL Simulator of Permanent Magnet Synchronous Motor Drive

FPGA-based Real-time HIL Simulator of Permanent Magnet Synchronous Motor Drive

In a real-time control systems, reliability plays a key role. This topic is closely related to a control algorithm design as well as its effective implementation. The In the Loop testings such as Model In the Loop (MIL), Software In the Loop (SIL), Processor In the Loop (PIL) and Hardware In the Loo...

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Bibliographic Details
Published in:2021 IEEE 19th International Power Electronics and Motion Control Conference (PEMC) pp. 552 - 558
Main Authors: Janous, Stepan, Talla, Jakub, Kosan, Tomas, Peroutka, Zdenek
Format: Conference Proceeding
Language:English
Published: IEEE 25-04-2021
Subjects:
Computational modeling
Hardware
Permanent magnet motors
Predictive models
Real-time systems
Semiconductor device modeling
Synchronous motors
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Summary:In a real-time control systems, reliability plays a key role. This topic is closely related to a control algorithm design as well as its effective implementation. The In the Loop testings such as Model In the Loop (MIL), Software In the Loop (SIL), Processor In the Loop (PIL) and Hardware In the Loop (HIL) are the popular methods for verification and validation of embedded systems in different stage of development. Especially, HIL is the popular way of embedded system verification in a real-time conditions. For HIL real-time models of electric drives with incorporation of inverter switching, dead-time effects etc. the field programmable gate arrays (FPGAs) are the most popular target hardware platform. This paper is focused on development of the real-time HIL simulator of permanent magnet synchronous motor (PMSM) drive, containing detailed model of PMSM motor together with the model of the power converter. It allows us to address usually un-modeled phenomenons such as dead-times, voltage drops on the semiconductor components as well as nonlinear magnetic characteristics. The algorithm is implemented in low cost FPGA and in order to minimize the computational time, a fixed point calculation together with high level of pipelining is used. The developed HIL simulator is tested and the results are validated by comparison with the real laboratory drive with the identical parameters.
ISSN:2473-0165
DOI:10.1109/PEMC48073.2021.9432517