Litcius/Paper detail

Digital Current Controller With a Novel Active Damping Design for IPMSM

Shuying Yang, Qishuai Wang, Zhen Xie, Xing Zhang, Liuchen Chang

2021IEEE Transactions on Energy Conversion24 citationsDOI

Abstract

Internal model control gets wide attentions in electric drives for its outstanding robustness. Underdamped oscillations however, always can be seen in the synchronous <i>d</i>- and <i>q</i>- axis components of the stator currents if without proper extra damping elements included, especially under the low sampling to fundamental frequency ratios. The reasons for these oscillations are analyzed in the discrete-time domain other than as usually done in the continuous-time domain. Following that, a distinctive active damping matrix is proposed for the current closed-loop control of interior permanent magnet synchronous motors (IPMSMs). As a result, the anti-disturbance capability is enhanced, allowing the oscillations, often seen in the <i>d</i>- and <i>q</i>-axis current components, suppressed very well. Compared with other damping methods, the typical PI structure is still retained, which is desired on the point of engineering view. At last, the analysis as well as the damping effectiveness is validated through experiments.

Topics & Concepts

Control theory (sociology)StatorRobustness (evolution)Robust controlFrequency domainCurrent loopTime domainCurrent (fluid)Synchronous motorPermanent magnet synchronous motorMachine controlControl systemEngineeringComputer scienceMagnetControl engineeringControl (management)Electrical engineeringGeneBiochemistryChemistryArtificial intelligenceComputer visionSensorless Control of Electric MotorsElectric Motor Design and AnalysisMultilevel Inverters and Converters