Shahid Beheshti University, Shahid Beheshti University, Iran
Ariba Farrokh is a distinguished researcher in electrical engineering, specializing in permanent magnet machines and hysteresis motors. With a strong academic background from Shahrood University of Technology, she has made significant contributions to the field through her research and publications. Her expertise lies in modeling, analysis, and design of electrical machines, with a focus on improving performance and efficiency. Ariba’s work has been recognized through various publications in reputable conferences and journals, showcasing her dedication to advancing electrical engineering.
Profile
orcid
scholar
🎓 Education
– Ph.D. in Electrical Engineering: Shahrood University of Technology, Iran (Focus on permanent magnet machines)- (link unavailable) in Electrical Engineering: Shahrood University of Technology, Iran (Focus on modeling and controlling hysteresis motors)- (link unavailable) in Electrical Engineering: Shahrood University of Technology, Iran
👨🔬 Experience
Ariba Farrokh has extensive research experience in electrical engineering, with a focus on:- *Modeling and analysis of electrical machines*: Hysteresis motors and permanent magnet machines- *Design and optimization of electrical machines*: Axial-field flux-switching permanent magnet motors- *Research and publication*: Published numerous papers in reputable conferences and journals
🔍 Research Interest
– *Electrical machine design and optimization*: Improving performance and efficiency of electrical machines- *Permanent magnet machines*: Design and analysis of axial-field flux-switching permanent magnet motors- *Hysteresis motors*: Modeling and controlling hysteresis motors using inverter-based power supply
Awards and Honors🏆
No specific awards or honors are mentioned in the provided information. However, Ariba’s publications in reputable journals and conferences demonstrate her recognition in the field of electrical engineering.
📚 Publications
1. Modeling and Analysis of the Effects of Changing the Supply Voltage on the Performance of a Hysteresis Motor 📊
2. Modeling and Performance Comparison of a Hysteresis Motor controlled by an inverter based power supply 💻
3. Design of Axial Field Flux Switching Motor with Improved Torque Ripple for Electric Vehicle Applications 🚗
4. Design and comparison of dual-stator axial-field flux-switching PM motors for electric vehicle application 🚗
5. A 2D hybrid analytical electromagnetic model of the dual-stator axial-field flux-switching permanent magnet motor 📊
6. Design of Dual-Rotor Dual-Stator Axial-Field Flux-Switching PM Motor with Low-Cogging Torque and Low-Torque Ripple 🔋
7. Design and Optimization of the Dual-Stator Axial-Field Flux-Switching PM Motor with High-Torque Density and Low-Cost 💸
8. Fast 2-D analytical model for axial-field flux-switching bar-permanent magnet motor ⚡️
9. Demagnetization and Fault-Tolerance Analysis in Dual‐Stator Axial‐Field Flux‐Switching Permanent Magnet Motor 🔋
10. A Comprehensive DOE-Optimization Method of Coaxial Magnetic Coupling for Aircraft Applications ✈️
Conclusion
The researcher demonstrates significant potential for the Best Researcher Award, with a strong academic background and notable research output. By addressing areas for improvement, such as interdisciplinary collaboration and journal publications, the researcher can further solidify their position as a leading expert in electrical engineering.