Wu Xiang

Xiang Wu

Associate Professor, College of Transportation, Tongji University

Phone

15105212760

Email

457005364@qq.com

Website

 wux@tongji.edu.cn

Biography

Wu Xiang, who obtained a doctoral   degree in engineering, is currently an associate professor and master's   supervisor at the School of Transportation, Tongji University. He is an IEEE   Member, Deputy Director of Science and Technology of Jiangsu Province (2020-2021),   and a member of the 2nd Youth Academic Committee on Power System Protection   and Control. He has presided over or participated in 2 National Natural   Science Foundation projects, 3 provincial and ministerial level projects, and   more than 10 enterprise cooperation projects. He has published over 60   high-level papers both domestically and internationally, and has been granted   more than 10 invention patents. His research interests include maglev and   rail transit traction converters and control, advanced control strategies for   motors in transportation vehicles, new wide bandgap power electronic   converters, and grid based energy storage technology.

Education   

Sep. 2013 - Jun. 2019,  China   University of Mining and Technology,    Ph.D. Candidate in Power Electronics and Electric Drives

Sep. 2009 - Jun. 2013,  China   University of Mining and Technology,    Bachelor's Degree in Electrical Engineering and Automation

Experience

Dec. 2025 – Present,  Tongji   University  College of Transportation   Engineering  Associate Professor

Jan. 2024 - Nov. 2025,  China   University of Mining and Technology    School of Electrical Engineering    Associate Professor

Jul. 2019 - Dec. 2023,  China   University of Mining and Technology    School of Electrical Engineering Lecturer

Research   interests

Projects Hosted:

1.      National Natural Science Foundation of China (Youth Program), Research   on Adjacent Four-Vector SVPWM and Multi-objective Optimization for Silicon Carbide-Based   Three-Level Inverters, project host, 2021-2023

2.      Jiangsu Provincial Natural Science Foundation (Youth Program), Research   on Common-Mode Voltage Suppression Strategies for Hybrid-Power-Device   Three-Level Inverters Based on Hybrid and Spread-Spectrum PWM, project   host, 2021-2023

3.      Shanxi Provincial Science and Technology Department Innovation Ecosystem   Support Project, Common Key Technologies and Applications for   High-Performance High-Power-Density Inverters, project host, 2023-2026

4.      Central Universities Fundamental Research Funds for Young Scholars, Common-Mode   Voltage Effects and Suppression PWM Strategies for Electric Vehicle   Inverters, project host, 2020-2021

5.      Industrial Project: Sensorless Full-Speed-Range Control for Permanent   Magnet Motors in Electric Compressors, project host, collaborated with a   leading company; successfully achieved mass production

6.      Industrial Project: Development of Electric Drive System for Heavy-Duty   Mining Trucks, project host

7.    Industrial Project: High-Power Permanent Magnet   Synchronous Motor Speed Control System for Belt Conveyors, project host;   successfully applied to multiple coal mine belt conveyor systems

8.    Industrial Project: Medium-Voltage High-Power   Three-Level Explosion-Proof Inverter, project host; successfully applied to   multiple coal mine belt conveyor systems

9.    Industrial Project: Medium-Voltage High-Power   Three-Level Permanent Magnet Hoist Speed Control System, project host;   successfully applied to multiple mine hoist systems

10.Industrial Project: Development of High-Power Energy   Storage Converter System, project host

Honors & Awards

Domestically developed megawatt-level high-performance four-quadrant DC   PWM speed control system, the Second Prize    of the 2022 China Coal Industry Science and Technology Award.

Publications

Ⅰ.Representative Papers in the Field of AC Motor Control

[1] New Adjacent Four-Vector Synthesis Principle-Based Phase Current   Reconstruction for PMSMs, IEEE Transactions on Power Electronics, 2025.（First Author）

[2] A   Unified Demodulation Method for High-Frequency Signal Injection-Based IPMSM   Sensorless Control , IEEE Transactions on Power Electronics, 2025.（First   Author）

[3] Random   Dual-Interval High-Frequency Square-Wave Voltage Injection Based Sensorless   Control of IPMSM Drives for Noise Reduction, IEEE Transactions on Power   Electronics, 2025.（First Author）

[4]   Sensorless Control of Permanent Magnet Synchronous Motor Based on Double-   Cost-Function Finite-Position-Set Phase-Locked Loop, IEEE Transactions on   Industrial Electronics,2024（First Author）

[5]   Maximum Torque per Ampere Control for IPMSM based on Sliding Mode Extremum   Seeking Control without Steady-state Oscillation, IEEE Journal of Emerging   and Selected Topics in Power Electronics,2025 （Corresponding Author）

[6] Review   and New Expansion of the Active Damping Strategy of the PMSM Drive System   with LC Sine Wave Filter, CES Transactions on Electrical Machines and   Systems,2025（First Author）

[7] An   Anti-DC Offset Interference Sensorless Control Method for PMSM Based on   Improved SMO and MDCF-FPS-PLL, IEEE Journal of Emerging and Selected Topics   in Power Electronics,2025 （First Author）

[8]   Sensorless Control of IPMSM Equipped With LC Sinusoidal Filter Based on   Full-Order Sliding Mode Observer and Feedforward QPLL,IEEE Transactions on   Power Electronics, 2024.（First Author）

[9] Sensorless Control of Permanent Magnet Synchronous Motor Based on   Improved Orthogonal Phase-Locked Loop, Transactions of China   Electrotechnical Society, 2023 (First Author)

[10] Resonance Suppression Parameter Design for Current Controller of   Interior Permanent Magnet Synchronous Motor with LC Sine Wave   Filter, Transactions of China Electrotechnical Society, 2023 (First   Author)

[11]    A Comparative Study of Sensorless Control of PMSM Realized by SMO, IET   Power Electronics, 2020, （Corresponding Author）.

[12]    Second-Order Lead Compensator-Based Quadrature PLL for Sensorless   Interior Permanent Magnet Synchronous Motor Control, IET Power Electronics,   2020, 13(3): 568-575.（Corresponding Author）

[13]  Sensorless   flux adaption DTFC of an IPMSM based on an active flux-based MTPA and an   adaptive second-order sliding mode observer, IET Power Electronics, 2020（Corresponding   Author）

[14] Finite   Position Set-Phase Locked Loop with Low Computational Burden for Sensorless   Control of PMSM Drives,  IEEE Transactions on Industrial   Electronics,2022.

[15]   Sensorless Control of PMSM Drives Using Reduced Order Quasi Resonant-Based   ESO and Newton–Raphson Method-Based PLL,IEEE Transactions on Power   Electronics, 2022.

[16]   Optimization Design of PMSM Sensorless Control Using Generalized Integrator,   IEEE Transactions on Industrial Electronics, 2023

[17]   Sensorless Control of IPMSM Drives Using High-Frequency Pulse Voltage   Injection With Random Pulse Sequence for Audible Noise Reduction, IEEE   Transactions on Power Electronics,2023

[18] Novel   Random High-Frequency Square-Wave and Pulse Voltage Injection Scheme-Based   Sensorless Control of IPMSM Drives, IEEE Journal of Emerging and Selected   Topics in Power Electronics, 2023

[19]   Design of Double-LCC-Compensated Wireless PMSM System With Variable DC-Link   Voltage Considering Efficiency Optimization and Dynamic   Improvement, IEEE Transactions on Power Electronics,2024

[20] A   Novel Computationally Efficient Finite Position Set-Phase Locked Loop for   Low-Speed Sensorless IPMSM Control, IEEE Transactions on Power   Electronics,2025,（Corresponding Author）

Ⅱ. Representative Research Papers on Topology Optimization, Design, and   Modulation Techniques of Traction Converters

[1]  Optimized   Common-Mode Voltage Reduction PWM for Three-Phase Voltage-Source Inverters,   IEEE Transactions on Power Electronics, 2016, 31(4): 2959-2969.（First   Author）

[2] Virtual-Space-Vector   PWM for A Three-Level Neutral-Point-Clamped Inverter With Unbalanced   DC-links, IEEE Transactions on Power Electronics, 2018, 33(3):2630-2642.（First   Author）

[3]   Fast-Processing Implementation of Current-Ripple-Losses-Optimized Common-mode   Voltage Reduction PWM, IEEE Transactions on Power Electronics, 2019,   34(4):3860-3870.（First Author）

[4]   A Hybrid PWM for Three-Level Inverter With   Unbalanced DC-links, IEEE Journal of Emerging and Selected Topics in Power   Electronics, 2018, 6(1):1-15.（First Author）

[5]   Multi-Objective Satisfactory Optimization PWM Strategy for Three-Phase   Voltage-Source Inverters, Proceedings of the CSEE, 2016, 36(6):   1674-1685. (First Author)

[6]    A Generalized Algorithm to Eliminate Spikes of Common-Mode Voltages for   CMVRPWM, IEEE Transactions on Power Electronics, 2016, 31(9): 6698-6709.（Corresponding   Author）

[7]    An Improved Simplified PWM for Three-Level Neutral Point Clamped Inverter   Based on Two-Level Common-mode Voltage Reduction PWM, IEEE Transactions on   Power Electronics, 2020, （Corresponding Author）.

[8]    A Simplified PWM Strategy for a Neutral-Point-Clamped (NPC) Three-Level   Converter With Unbalanced DC links, IEEE Transactions on Power Electronics,   2016, 31(4): 3227-3238.

[9]    Optimized Switching Finite Control Set Model Predictive Control of NPC   Single-Phase Three-Level Rectifiers, IEEE Transactions on Power Electronics,   2020.

[10] A   Dual-Vector Model Predictive Control Method With Minimum Current THD，IEEE   Transactions on Power Electronics, 2021. （Corresponding Author）

[11] An   optimal zero-sequence voltage injection-based common-mode voltage reduction   pulse-width modulation for the reduction of common-mode voltages in both   amplitude and third-order component, IET Power Electronics, 2022,（First   Author）

[12]   Neutral-point voltage control of the three-level inverter in permanent magnet   synchronous motor based direct-drive belt conveyor , Computers and Electrical   Engineering,2023,（First Author）

[13]   Dynamic Improvement and Efficiency Optimization of Wireless Power Transfer   Systems Using Improved FCS-MPC and P&O Methods,IEEE Transactions on Power   Electronics,2023

[14]   Virtual space vector PWM with reduced CMV for three-level inverters under   unbalanced DC-links, Journal of power electronics, 2024（First   Author）

[15]   Virtual Space Vector Overmodulation Strategy for NPC Three-Level Inverters   With Common-Mode Voltage Suppression,IEEE Transactions on Power   Electronics,2024

[16]   Optimized Asymmetrical Switching Sequences-Based Model-Predictive Control for   Three-Level T-Type Inverters, IEEE Journal of Emerging and Selected Topics in   Power Electronics,2023

[17]   Enhancing the Neutral Point Potential Balance Capability Based on Zero   Sequence Voltage Range Expansion for Seven-Segment RCMV-PWM of Three-level   Inverter, IEEE Journal of Emerging and Selected Topics in Power   Electronics,2025（First Author）

[18]   Improved Model-Free Predictive Current Control With Forgetting Factor, IEEE   Transactions on Industrial Electronics,2025.

[19]   Enhanced Accuracy Finite-Control-Set Model-Predictive Control for Three-Phase   Three-Level NPC Inverter, IEEE Transactions on Power Electronics,2025.

[20]   Virtual space vector PWM with reduced CMV for three-level inverters under   unbalanced DC-links, J. Power Electron.，2025（First Author）.