Jingxia Wang is a promising young researcher and lecturer in the School of Mechanical Engineering at the University of Shanghai for Science and Technology. Her academic journey and research achievements reflect a strong commitment to advancing the field of electrical and electromechanical systems. With a specialized focus on the electromagnetic-thermal coupling and iron loss analysis in electric machines, she has contributed significantly to the theoretical and applied aspects of energy conversion technologies. Her research addresses key challenges in improving the performance and efficiency of permanent magnet and induction motors under inverter supply, aligning with the growing demands for high-performance electric drives. She has published several high-quality articles in top-tier journals such as IEEE Transactions on Industrial Electronics and IEEE Transactions on Energy Conversion, establishing her as a rising expert in her field. In addition to scholarly publications, she has also contributed to patented innovations in the domain of loss calculation and electromagnetic simulation. Her active participation in national research funding programs and leadership roles in funded projects underscore her academic capabilities. Jingxia Wang continues to grow as an independent researcher with a clear vision and technical depth, making her a strong candidate for prestigious academic recognition, including the Best Researcher Award.

Professional Profile

• Scopus Profile

Education

Jingxia Wang has built her academic foundation through a robust and consistent educational trajectory in the field of electrical engineering. She completed her undergraduate studies at Northeast Electric Power University from September 2011 to July 2015, where she obtained a Bachelor’s degree in Electrical Engineering and Automation. Her early training laid the groundwork for deeper technical exploration and problem-solving in electric machine systems. Driven by academic passion and curiosity, she pursued doctoral studies at Southeast University—one of China’s top institutions—in the field of Electrical Engineering from September 2015 to March 2022. During her Ph.D., she specialized in iron loss modeling, magnetic field modulation, and electromagnetic-thermal coupling in motor systems, which later became core aspects of her research focus. Her doctoral work contributed to high-impact publications and several patents, indicating both theoretical innovation and practical relevance. While she has not undertaken a postdoctoral fellowship, the depth and breadth of her Ph.D. training have equipped her with the technical acumen necessary for independent research and academic leadership. Her educational background reflects strong theoretical grounding and hands-on experience with complex computational models and machine dynamics, positioning her well within the academic and industrial research community.

Professional Experience

Jingxia Wang has been serving as a Lecturer at the School of Mechanical Engineering, University of Shanghai for Science and Technology since June 2022. In this capacity, she has been actively engaged in both teaching and research activities related to electric machinery and computational modeling. Her professional role involves mentoring students, contributing to curriculum development, and leading research projects funded by national and municipal agencies. Although she does not have postdoctoral experience, her transition from Ph.D. to faculty position demonstrates her capability to operate as an independent researcher. As a principal investigator, she has led and managed a National Natural Science Foundation Youth Fund project focused on inverter-fed induction motors and magnetic loss analysis, reflecting her technical leadership and project management skills. Additionally, she has participated in and contributed to major collaborative research projects funded by NSFC and the Shanghai Science and Technology Commission. Her involvement in interdisciplinary work, such as multi-physics coupling analysis, further expands the relevance of her professional profile across mechanical and electrical domains. Jingxia’s teaching experience and project responsibilities showcase a balanced academic career that combines foundational research, practical application, and knowledge dissemination, strengthening her suitability for academic recognition and further career advancement.

Research Interests

Jingxia Wang’s research interests lie at the intersection of electrical machine design, electromagnetic modeling, and multiphysics simulation. Her work primarily focuses on accurate calculation and analysis of iron loss in permanent magnet and induction motors, especially under pulse-width modulation (PWM) inverter supply. One of her core contributions has been the application of general airgap magnetic field modulation theory to quantify iron loss and stray load loss more effectively. Additionally, she has expanded her research into bidirectional coupling between electromagnetic and thermal fields, a critical area for enhancing the design accuracy and reliability of electric machines in dynamic environments. Her interests also include finite element analysis (FEA), fast calculation algorithms, and field-oriented control techniques for electric drives. Through her ongoing research, she addresses challenges in improving energy efficiency, thermal stability, and operational reliability in motor systems used in transportation, robotics, and industrial automation. Her work bridges theoretical electromagnetics with real-world implementation, making her contributions both academically valuable and industrially applicable. As sustainability and electrification become global priorities, her research remains timely and impactful, paving the way for smarter, more efficient electromechanical devices and systems.

Research Skills

Jingxia Wang possesses a comprehensive set of research skills that support her specialization in electric machine systems and computational modeling. She is highly proficient in electromagnetic field theory and loss analysis techniques, particularly in inverter-fed motors. Her expertise includes the application of general airgap field modulation theory, finite element analysis (FEA), and the development of fast calculation methods for complex electromechanical systems. She is also skilled in thermal simulation and electromagnetic-thermal bidirectional coupling analysis, which are crucial for evaluating machine performance under varying operational conditions. Her programming capabilities and simulation experience with industry-standard tools enable her to handle multi-domain simulations efficiently. Furthermore, she has experience with research project design, proposal writing, data interpretation, and results dissemination through high-impact publications. Her skill set extends to intellectual property development, as evidenced by her co-invention of several patents. Jingxia is adept at translating theoretical models into practical applications, making her a valuable collaborator in both academic and industrial research environments. Her methodological rigor, combined with strong analytical and communication skills, enhances her ability to lead independent research and mentor students in advanced engineering topics.

Awards and Honors

Although specific awards are not listed beyond patents and project funding, Jingxia Wang’s academic track record includes several forms of recognition that demonstrate her research excellence and innovative capabilities. She has received competitive research funding from the National Natural Science Foundation of China, including a Youth Fund project, which is highly regarded for supporting emerging researchers with outstanding potential. Her leadership in this and other municipal projects such as the Shanghai “Science and Technology Innovation Action Plan” reflects recognition by key funding bodies and the research community. Her scholarly work has appeared in prestigious journals such as IEEE Transactions on Industrial Electronics and IEEE Transactions on Energy Conversion, often as the sole first author—a significant academic distinction. She has also co-invented multiple patents related to magnetic field modulation, iron loss calculation, and electromagnetic-thermal modeling, highlighting her contribution to applied research and technology transfer. These honors, combined with her early career achievements, serve as strong indicators of her research strength, impact, and upward trajectory. As her academic career progresses, she is well-positioned to attain further distinctions at both national and international levels.

Conclusion

Jingxia Wang emerges as a highly capable and driven early-career academic with a solid foundation in electrical engineering and a sharp focus on energy-efficient electromechanical systems. Her contributions span theoretical innovation, computational modeling, and practical engineering solutions—making her research both relevant and forward-looking. Through high-impact publications, funded projects, and patented technologies, she has already made a significant mark in the field of electric machine analysis. Her ability to integrate electromagnetic theory with thermal dynamics in machine modeling reflects a rare depth of technical insight and interdisciplinary thinking. While she could further benefit from postdoctoral experience or international research exposure, her current achievements speak to her strong potential for future academic and industrial leadership. As a researcher who demonstrates clarity in focus, rigor in methodology, and creativity in solving complex engineering problems, Jingxia Wang is a compelling nominee for the Best Researcher Award. Her trajectory suggests sustained contributions to science and engineering, with the capacity to influence not only academic discourse but also real-world applications in energy and automation systems.

Publications Top Notes

1. Double-virtual-vector-based model predictive torque control for dual three-phase PMSM
   Authors: Qingqing Yuan, Rongyan Xiao, Jingxia Wang, Kun Xia, Wei Yu
   Journal: Electronics (Switzerland)
   Year: 2025