6533b7dafe1ef96bd126e2dc
RESEARCH PRODUCT
Robust control for high performance induction motor drives based on partial state-feedback linearization
Roberto RabbeniAngelo AccettaAntonino SferlazzaFilippo D'ippolitoMarcello PucciFrancesco AlongeMaurizio Cirrincionesubject
0209 industrial biotechnologyEngineeringComputer scienceStator020209 energy02 engineering and technologyIndustrial and Manufacturing Engineeringlaw.invention020901 industrial engineering & automationSettore ING-INF/04 - AutomaticaControl theorylawLinearizationRobustness (computer science)0202 electrical engineering electronic engineering information engineeringTorqueFeedback linearizationElectrical and Electronic EngineeringInduction motorfeedback linearizationComputer simulationbusiness.industry020208 electrical & electronic engineeringControl engineeringPartial state feedbackMagnetic coreControl and Systems Engineeringrobust control.Feedback linearization (FL)Robust controlbusinessInduction motorrobust controldescription
This paper deals with a robust input-output feedback linearization control technique for induction motors. Indeed, classic feedback linearization presents two main disadvantages: 1) the accuracy of the dynamic model; and 2) the corresponding correct knowledge of the model parameters. To address this issue, the linear controller has been substituted with a suitably controller designed to be robust to the variations of the main parameters of the induction motor, like stator and rotor resistances, and the three-phase magnetizing inductance. The proposed controller has been tested both in numerical simulation and experimentally on a suitably designed test setup. Moreover, it has been compared with the classical feedback linearization based on linear controllers, highlighting the improvements in terms of dynamic performance, when parameter variations occur. Results confirm a significant increase of the robustness of the controller against parameter variations.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2019-01-01 |