| Title |
Optimal Design of a Variable Reluctance Resolver to Minimize Position Error |
| Authors |
강정문(Jungmoon Kang) ; 최길수(Gilsu Choi) |
| DOI |
https://doi.org/10.5370/KIEE.2024.73.1.44 |
| Keywords |
VR Resolver; Design optimization Phase shift; Accuracy; Angle error; Transformation ratio |
| Abstract |
The precision of position estimation in VR resolvers significantly relies on the harmonic components present in the induced voltage across the secondary winding. The degraded accuracy can be compensated by carefully designing the stator windings and core geometry. This paper presents an optimized design process aimed at minimizing the position error of VR resolvers. The alterations in the resolver output signal's position information, resulting from the phase shift of the stator windings, third harmonic injection-based rotor geometry modifications, and changes to the stator core shape, are thoroughly analyzed using finite element analysis (FEA). Subsequently, a genetic algorithm-based optimization technique is applied to construct an optimal design process that effectively minimizes the position error in VR resolvers. Case study results demonstrate an approximately 80% enhancement in position estimation accuracy for the optimal model compared to the initial model. |