Litcius/Paper detail

Decoupled Design of Fault-Tolerant Control for Dual-Three-Phase IPMSM With Improved Memory Efficiency and Reduced Current RMS

Guodong Feng, Chunyan Lai, Weiwen Peng, Narayan C. Kar

2021IEEE Transactions on Transportation Electrification25 citationsDOI

Abstract

Fault tolerance is critical to real-time control of the dual-three-phase interior permanent magnet synchronous machine (IPMSM). This article proposes an efficient decoupled design for fault-tolerant control (FTC) of dual-three-phase IPMSMs to improve the average torque and minimize the current root mean square (rms) for torque ripple and loss reduction under the open-phase fault. Specifically, the FTC design is divided into two subtasks to derive the FTC strategy with a simplified design, in which the two subtasks are the fundamental current design and the harmonic current design. The optimal current solution to FTC is derived in a memory- and computation-efficient way. The proposed solution can achieve better transient performance and reduce the current rms for FTC, which is critical to practical applications with dynamic changing loads. In comparison with existing methods, the proposed FTC can effectively reduce the request of memory and computation resources from the drive system. Extensive experiments and comparisons are conducted to evaluate the proposed FTC on a laboratory dual-three-phase IPMSM.

Topics & Concepts

Control theory (sociology)Fault toleranceTorque rippleComputer scienceDual (grammatical number)TorqueTransient (computer programming)Reduction (mathematics)ComputationRippleCurrent (fluid)Fault (geology)HarmonicControl (management)Direct torque controlEngineeringVoltageMathematicsAlgorithmInduction motorElectrical engineeringGeometryQuantum mechanicsDistributed computingLiteratureArtificial intelligenceThermodynamicsPhysicsOperating systemSeismologyArtGeologyMultilevel Inverters and ConvertersMicrogrid Control and OptimizationSensorless Control of Electric Motors