宋文胜 教授

博士生导师

硕士生导师

个人信息Personal Information


学历:博士研究生毕业

学位:工学博士学位

毕业院校:西南交通大学

学科:电气工程. 电力电子与电力传动

所在单位:集成电路科学与工程学院(西南交大-中车时代微电子学院)

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  • 科研项目

    1)纵向项目:

    [14] 国家自然科学基金-铁路基础研究联合重点项目”高速列车碳化硅牵引系统多物理场耦合机理及关键技术研究(No. U2368206)” 2024.01~2027.12, 主持

    [13] 四川省青年科技创新研究团队项目“电力牵引与控制(No. 22CXTD0055)”,2022.01~2024.12, 主持;

    [12] 国家自然科学基金-优秀青年基金项目“高速列车电力牵引系统关键技术(No. 52022084)”,2021.01~2023.12, 主持;

    [11] 国家自然科学基金-高铁联合重点项目“高速列车牵引系统健康监测、故障诊断与安全控制技术研究(No.U1934204)”, 2020.01~2023.12, 主研;

    [10] 国家自然科学基金重点项目“车载大功率电力电子变压器鲁棒容错控制研究 (No.61733015)”, 2018.01-2022.12,主研;

    [9] 国家重点研发计划项目任务“复杂供电与线路条件下电力电子变压器-电机驱动系统耦合模型及其协同控制研究( No. 2017YFB1200901 )”, 2017.07- 2020.06, 主持;

    [8] 国家重点研发计划项目任务“基于宽禁带半导体器件高频化应用电路拓扑研究 ( No. 2017YFB1200902 )”, 2017.07-2020.06, 主研;

    [7] 国家重点研发计划项目公开任务“列车多效应耦合及智能控制技术研究(No. 2016YFB1200502)” 2016.07-2020.07,主研;

    [6] 国家自然科学面上基金项目“基于电力电子变压器的高速列车牵引传动系统网侧控制技术研究 (No.51577160)”,2016.01-2019.12,主持;结题优秀

    [5] 国家自然科学青年基金项目“三电平电力牵引变流器网侧谐波抑制优化控制方法研究(No.51207131)”,2013.01-2015.12,主持 ;结题优秀

    [4] 国家自然科学基金-高铁联合基金重点项目“高速列车车网电气安全防护理论与方法研究 (No. U1434203)”,2015.01-2018.12,主研;

    [3] 国家科技支撑计划子课题 “二、三型车牵引传动系统优化控制策略仿真研究(No.2009BAG12A05-10)” , 2009.01-2012.12, 主研;

    [2] 国家科技支撑计划子课题 “高速货运机车牵引变流器控制策略仿真(No. 2007BAA12B06-02)”,2007.01-2010.12,主研;

    [1] 铁道部“铁路装备现代化引进技术消化吸收再创新重大攻关课题” 牵引传动与网络控制”, 2006.01- 2008.12, 主研;


     

    2)横向项目:

       [21] 国家铁路集团科技研究开发计划重大课题“动车组关键部件数字孪生技术研究,2023.07-2024.12, 参与

       [20] 国铁集团基础研究开放课题“基于有源滤波的牵引变流器直流环节二次脉动电压抑制技术研究”,2023.09-2025.12, 主持

    [19] 企业技术开发合作项目“牵引电机绝缘及轴承故障机理和诊断技术研究”, 2023.07- 2025.07, 主持

    [18] 企业技术开发合作项目“整车控制技术优化提升”, 2022.08-2023.12, 主持

    [17] 企业技术开发合作项目“牵引MBD平台的用户界面实现技术”, 2023.01- 2023.12, 主持

    [16] 企业技术开发合作项目“机车牵引系统半实物仿真模型委托开发”, 2021.12- 2022.11, 主持

    [15] 国铁集团科技开发重点项目“列车电力牵引系统极低速再生制动能力提升技术”, 2019.12- 2022.06, 参与

    [14] 企业技术开发合作项目“轨道交通多车“车-网”耦合仿真研究”, 2020.05- 2020.12, 主持

    [13] 企业技术开发合作项目“无LC谐振回路牵引变流器控制技术开发”, 2018.09- 2020.04, 主持

    [12] 企业技术开发合作项目“多相永磁电机直驱系统及其在城轨新能源机车上的应用开发”, 2017.10-2020.05, 主持

    [11] 企业技术开发合作项目“CRH380B型动车组牵引变压器车顶主断路器操作过电压仿真分析”, 2019.12- 2020.01, 主持

    [10] 企业技术开发合作项目“高速铁路供电系统与动车组牵引传动系统稳定性分析方法研究”, 2018.05-2019.01, 主持

    [9] 企业技术开发合作项目“列车牵引系统计算软件开发”, 2017.11-2018.12, 主持

    [8] 企业技术开发合作项目“单相脉冲整流器控制软件开发”, 2016.05-2017.12, 主持

    [7] 企业技术开发合作项目“整流器控制算法开发与测试”, 2015.06-2016.12,主持;

    [6] 企业技术开发合作项目“牵引变流器PWM算法FPGA开发”, 2016.05-2017.05, 主持;

    [5] 企业技术开发合作项目“列车电气系统匹配与仿真平台”, 2015.06-2016.06,主持;

    [4] 企业技术开发合作项目“CRH3型动车组牵引传动系统故障建模及诊断研究”, 2012.05- 2013.12,主持;

    [3] 企业技术开发合作项目“高速动车组电传动系统参数设计及仿真分析计算软件”, 2013.03-2014.07, 主持;

    [2] 企业技术开发合作项目“高速动车组牵引控制优化技术研究”,2011.05 - 2012.12,主研;

    [1] 企业技术开发合作项目 “HXD2C型电力机车牵引主传动系统及其辅助系统参数计算与仿真”, 2010. 10- 2011. 09,主研;



  • 发明专利:

    1)授权专利:

    [1] 宋文胜, 吴瑕杰, 冯晓云, 王顺亮, 葛兴来. 低载波比在线计算多模式空间矢量脉宽调制软核, 发明专利,专利号:ZL201410145537.7, 2016817日授权

    [2] 宋文胜, 马俊鹏, 熊成林, 冯晓云, 葛兴来, 王青元. 一种单相工频系统无锁相环瞬时功率计算及无锁相环频率补偿算法, 发明专利, 专利号:ZL201410384303.8, 2016824日授权

    [3] 宋文胜, 吴瑕杰, 熊成林,葛兴来,王青元,冯晓云. 一种适用于三相级联H桥型变换器的简化多电平空间矢量脉宽调制方法及其调制软核, 发明专利专利号:ZL201510181313.6, 2017415日授权

    [4] 宋文胜, 侯聂, 武明义, 葛兴来,冯晓云,王青元,熊成林. 一种应用于全桥隔离DC-DC变换器的直接功率控制方法, 发明专利, 专利号:ZL201510552721.8, 2017616日授权

    [5] 宋文胜, 侯聂, 武明义, 葛兴来,冯晓云, 王青元,熊成林. 提高全桥隔离DC-DC变换器输出电压动态响应的负载电流前馈控制方法, 发明专利, 专利号:ZL2015105274303201.5, 2017711日授权

    [6] 宋文胜, 侯聂, 武明义, 葛兴来, 冯晓云, 王青元, 熊成林. 一种实现全桥隔离DC-DC变换器降压变换模式最小电流应力的虚拟功率控制方法, 发明专利,专利号:ZL201510280715.1, 2017711日授权

    [7] 宋文胜, 侯聂, 武明义, 葛兴来, 冯晓云, 王青元, 熊成林. 一种应用于全桥隔离DC-DC变换器的归一化相移控制方法,发明专利, 专利号:ZL201510391177.3, 2018316日授权

    [8] 宋文胜, 侯聂, 马俊鹏,冯晓云,葛兴来,王青元. 一种应用于BUCK电路的准定频峰值电流控制方法, 发明专利,专利号:ZL201510262796.2, , 20180504日授权

    [9] 宋文胜,薛诚,武雪松. 一种五相永磁同步电机有限集模型预测电流控制方法,发明专利,专利号:ZL201611214528.4, 20181030日授权

    [10] 宋文胜,薛诚,武雪松. 一种五相永磁同步电机模型预测转矩控制方法,发明专利,专利号:ZL201710022345.0,  20181225日授权

    [11] 宋文胜,马俊鹏,冯晓云. 一种单相脉冲整流器低开关频率模型预测功率控制算法,发明专利,专利号:ZL201611125974.8,  2019129日授权

    [12] 宋文胜,刘 碧,余彬,武明义. 多模块全桥隔离DC-DC变换器轻载功率协同控制方法及装置,发明专利,专利号:ZL201710402409.X2019416日授权

    [13] 宋文胜,刘 碧,马俊鹏. 一种单相脉冲整流器电流内环控制器的优化方法,发明专利,专利号:ZL201711086336.4,  2019813日授权

    [14] 宋文胜,安 峰,杨柯欣. 双有源全桥DC-DC变换器的模型预测单相移控制方法,发明专利,专利号:ZL201711266069.920191021日授权

    [15] 宋文胜,安 峰,杨柯欣. 双有源全桥DC-DC变换器电流应力优化双相移控制方法,发明专利,专利号:ZL201711266394.520191113日授权

    [16] 宋文胜,安 峰,杨柯欣. 双有源全桥DC-DC变换器的三重相移无差拍优化控制方法,发明专利,专利号:ZL201810212894.920200119日授权

    [17] 宋文胜,安 峰,杨柯欣. 电力电子牵引变压器中DC-DC变换器的优化功率平衡方法,发明专利,申请号:ZL201810213057.820200114日授权

    [18] 宋文胜,安 峰,冯晓云. 输入串联输出并联全桥DC-DC变换器多模块优化功率平衡方法,发明专利,专利号:ZL201810612868.520200609日授权

    [19] 宋文胜,刘碧,冯晓云. 一种单相脉冲整流器电网电压估算方法,发明专利,专利号:ZL201811515084.720200904日授权

    2)申请专利:

    [20] 宋文胜,余彬,郭永琪,李建新,冯晓云,王青元,孙鹏飞,王嵩,黄景春 一种基于虚拟电压矢量的五相逆变器共模电压抑制方法,发明专利,申请号:ZL202010406136.8,2020年05月14日


  • A. 出版著作:

    [1] 宋文胜, 冯晓云, . 电力牵引交流传动控制与调制技术, 科学出版社, 2014

    [2]宋文胜,周国华 主编. 电力电子技术,科学出版社,2024年

    B. 部分代表性期刊论文:

    —————————————IEEE Journals————————————————

    [50] Song W, Zou Y, Ma C, Zhang S. Digital Twin Modelling Method of Three-phase Inverter-driven PMSM Systems for Parameter Estimation. IEEE Transactions on Power Electronics, 2023, (已录用)

    [49] Zhang S, Song W*, Cao H, Tang T, Zou Y. A Digital-Twin-Based Health Status Monitoring Method for Single-Phase PWM Rectifiers. IEEE Transactions on Power Electronics, 2023, 38(11): 14075 – 14087.

    [48] Deng Y, Song W*, Yin S, Zhong M, Chen J, Feng X. Zero-Backflow Power Control Scheme of Dual Bridge Series Resonant DC–DC Converters With High-Accuracy Time Domain Modeling. IEEE Transactions on Power Electronics, 2023, 38(9): 10985 - 10996.

    [47] Tang T, Song W*, Yang K and Chen J. A Junction Temperature Online Monitoring Method for IGBTs Based on Turn-off Delay Time. IEEE Transactions on Industry Applications, 2023, 59(5): 6399-6411.

    [46] Deng Y, Song W*, Yin S, Zhong M, Yang K, Feng X. A Model Predictive Control Scheme without Current Sensor of Dual Active Bridge DC-DC Converters: Improving Dynamic Performance and Reducing Hardware Cost. IEEE Transactions on Transportation Electrification, 2023, 9(2): 2916 – 2928.

    [45] Li J, Song W*, Liu B, Guo J, Wu Y, Li Y. A Comparative Study of Current Harmonics and Switching Frequency with Different Pulse Patterns in duty-cycle-based Model Predictive Current Control. IEEE Transactions on Industrial Electronics, 2023, 70(11): 10891-10901.

    [44] Yang K, Song W*, Tang T, Chen J. Online Monitoring Method of P-I-N Diode Temperature Based on Maximum Recovery Current. IEEE Transactions on Power Electronics, 2023, 38(6): 7723-7732.

    [43] Mahmoud S. R. Saeed, Song W*, Yu B, Feng X. Generalized Deadbeat Solution for Model Predictive Control of Five-Phase PMSM Drives. IEEE Transactions on Power Electronics, 2023, 38(4):5178-5191.

    [42] Li J, Song W*, Yue H, Sun N, Ma C*, Feng R. An Improved MPC with Reduced CMV and Current Distortion for PMSM Drives under Variable DC-bus Voltage Condition in Electric Vehicles. IEEE Transactions on Power Electronics, 2023, 38(4):5167-5177.

    [41] Song W, Yin S, Deng Y, Zhong M. Steady-state performance optimization of Dual-Bridge Series Resonant DC/DC Converters. IEEE Journal of Emerging and Selected Topics in Industrial Electronics, 2023,11(2): 1767-1777.

    [40] Chen J, Xu J, Song W, Luo Q, Mantooth H. A. A Suppression Method for Gate-Source Voltage Oscillation with Clamping Function for GaN Devices. IEEE Transactions on Power Electronics, 2023, 38(2):1435-1439.

    [39] Song W, Zhong M, Deng Y, Yin S, Yu B. Model Predictive Power Control for Bidirectional Series Resonant Isolated DC–DC Converters with Steady-State and Dynamic Performance Optimization. IEEE Journal of Emerging and Selected Topics in Industrial Electronics, 2022, 3(3):604-615.

    [38] Mahmoud S. R. Saeed, Song W*, Huang L, Yu B. Double-Vector-Based Finite Control Set Model Predictive Control for Five-Phase PMSMs With High Tracking Accuracy and DC-Link Voltage Utilization. IEEE Transactions on Power Electronics, 2022, 37(12): 15234 – 15244.

    [37] Wang H, Yang S*, Song W, Teck O B. A Matrix Construction Based Capacitor Voltage Measuring Scheme for Modular Multilevel Converter with Reduced Voltage Sensors. IEEE Transactions on Power Electronics, 2022, 37(9): 10095 - 10100.

    [36] Liu H, Ma L*, Song W, Peng L. An Internal Model Direct Power Control with Improved Voltage Balancing Strategy for Single-Phase Cascaded H-Bridge Rectifiers. IEEE Transactions on Power Electronics, 2022, 37(8): 7629 - 7639.

    [35] Peng L, Ma L*, Song W, Liu H, A Simple Model Predictive Instantaneous Current Control for Single-Phase PWM Converters in Stationary Reference Frame, IEEE Transactions on Power Electronics, 2022, 37(7): 9241-9253.

    [34] Xue C, Ding L, Wu X, Li Y, Song W. A Model Predictive Control for Grid-Connected Current-Source Converter With Enhanced Robustness and Grid-Current Feedback Only, IEEE Journal of Emerging and Selected Topics in Power Electronics, 2022, 10(5): 5591- 5603.

    [33] Yu B, Song W*, Yang K, Guo Y, Mahmoud S. R. Saeed A Computationally Efficient Finite Control Set Model Predictive Control for Multiphase PMSM Drives. IEEE Transactions on Industrial Electronics, 2022, 69(12): 12066-12076.

    [32] Song W*, Mahmoud S. R. Saeed, Yu B, Li J, Guo Y. Model Predictive Current Control with Reduced Complexity for Five-Phase Three-Level NPC Voltage-Source Inverter. IEEE Transactions on Transportation Electrification, 2022, 8(2): 1906-1917.

    [31] Yu B, Song W*, Guo Y, Mahmoud S. R. Saeed. A Finite Control Set Model Predictive Control for Five Phase PMSMs with Improved DC-Link Utilization. IEEE Transactions on Power Electronics, 2022, 37(3): 3297 - 3307.

    [30] Yu B, Song W*, Guo Y. A Simplified and Generalized SVPWM Scheme for Two-Level Multiphase Inverters with Common-Mode Voltage Reduction. IEEE Transactions on Industrial Electronics, 2022, 69(2): 1378-1388.

    [29] Feng X, Yang S*, Liu S, Song W. Capacitor Voltage Round-robin Transmission Modes for MMC Distributed Control Systems. IEEE Transactions on Industrial Electronics, 2021, 68(12): 12935 - 12940.

    [28] Yu B. Song W*, Guo Y, Li J, Mahmoud S. R. Saeed. Virtual Voltage Vectors Based Model Predictive Current Control for Five-Phase VSIs with Common-Mode Voltage Reduction. IEEE Transactions on Transportation Electrification, 2021, 7(2): 706- 717.

    [27] Mahmoud S. R. Saeed, Song W*, Yu B, Xie Z. Low-Complexity Deadbeat Model Predictive Current Control for Open-Winding PMSM Drive with Zero-Sequence Current Suppression. IEEE Transactions on Transportation Electrification, 2021, 7(4): 2671-2682.

    [26] Song W, Xue C, Wu X, Yu B. Modulated Finite-Control-Set Model Predictive Current Control for Five-Phase Voltage-Source Inverter. IEEE Transactions on Transportation Electrification, 2021, 7(2): 718-729.

    [25] Yu B, Song W*, Li J, Li B, Mahmoud S. R. Saeed. Improved Finite Control Set Model Predictive Current Control for Five-Phase VSIs. IEEE Transactions on Power Electronics, 2021, 36(6): 7038-7048.

    [24 Liu B, Song W*, Li YW, Zhan B. Performance Improvement of DC Capacitor Voltage Balancing Control for Cascaded H-Bridge Multilevel Converters. IEEE Transactions on Power Electronics, 2021, 36(3): 3354 - 3366.

    [23] Song WZhong M, Luo S, Yang S. Model Predictive Power Control for Bidirectional Series Resonant Isolated DC-DC Converters with Fast Dynamic Response in Locomotive Traction System. IEEE Transactions on Transportation Electrification, 2020, 6(3): 1326 - 1337.

    [22] Mahmoud S. R. Saeed, Song W*, Yu B, Wu X. Low-Complexity Deadbeat Model Predictive Current Control with Duty Ratio for five-phase PMSM Drives. IEEE Transactions on Power Electronics, 2020, 35(11): 12085-12099.

    [21] Gong Z, Huang D, Habit U.K. Jadoon, Ma L, Song W. Sensor-Fault-Estimation-Based Tolerant Control for Single-Phase Two-Level PWM Rectifier in Electric Traction System. IEEE Transactions on Power Electronics, 2020, 35(11): 12274-12284.

    [20] Ma J, Wang X, Blaabjerg F, Song W, Wang S, Liu T. Multisampling Method for Single-Phase Grid-Connected Cascaded H-Bridge Inverters. IEEE Transactions on Industrial Electronics, 2020, 67(10): 8322-8334.

    [18] Ma J, Wang X, Blaabjerg F, Song W, Wang S, Liu T. Real-Time Calculation Method for Single-Phase Cascaded H-Bridge Inverters Based on Phase-Shifted Carrier Pulse Width Modulation. IEEE Transactions on Power Electronics, 2020, 35(1): 977 - 987.

    [17] Yang S, Wang H, Chen H, Song W*, Wang T. Probability-Based Modeling and Analysis for PS-PWM in an MMC Distributed Control System with Sub-Module Asynchrony. IEEE Transactions on Power Electronics, 2019,34(11): 10392 - 10397.

    [16] Hou N, Song W*, Li Y, Zhu Y, Zhu Y. A Comprehensive Optimization Control of Dual Active Bridge DC-DC Converters based on Unified-Phase-Shift and Power-Balancing Scheme. IEEE Transactions on Power Electronics, 2019,34(1): 826-839.

    [15] An F, Song W*, Yang K, Yang S, Ma L. A Simple Power Estimation with Triple Phase-Shift Control for the Output Parallel DAB DC-DC Converters in Power Electronic Traction Transformer for Railway Locomotive Application. IEEE Transactions on Transportation Electrification, 2019, 5(1):299-310.

    [14] Ma J, Wang X, Blaabjerg F, Harnefors L, Song W. Accuracy Analysis of the Zero-Order Hold Model for Digital Pulse width Modulation. IEEE Transactions on Power Electronics, 2018, 33(12): 10826-10834.

    [13] Wu X, Song W*, Xue C. Low-Complexity Model Predictive Torque Control Method Without Weighting Factor For Five-Phase PMSM Based On Hysteresis Comparators. IEEE Journal of Emerging and Selected Topics in Power Electronics, 2018, 6(4): 1650-1661.

    [12] An F, Song W*, Yu B, Yang K. Model Predictive Control with Power Self-balancing of the Output Parallel DAB DC-DC Converters in Power Electronic Traction Transformer. IEEE Journal of Emerging and Selected Topics in Power Electronics, 2018, 6(4):1806-1818.

    [11] Xue C, Song W*, Wu X, Feng X. A Constant Switching Frequency Finite-Control-Set Predictive Current Control Scheme of Five-Phase Inverter with Duty Ratio Optimization. IEEE Transactions on Power Electronics, 2018, 33(4): 3583-3594.

    [10] Ma J, Song W*, Wang X, Blaabjerg F, Feng X. Low-Complexity Model Predictive Control of Single-Phase Three-Level Rectifiers with Unbalanced Load. IEEE Transactions on Power Electronics, 2018, 33(10): 8936-8947.

    [9] Ma J, Song W*, Wang S, Feng X. Model Predictive Direct Power Control for Single Phase Three-Level Rectifier at Low Switching Frequency. IEEE Transactions on Power Electronics, 2018, 33(2): 1750-1759.

    [8] Wang S, Song W*, Ma J, Zhao J, Feng X. Study on Comprehensive Analysis and Compensation Scheme for the Line Current Distortion in Single-Phase Three-Level NPC Converters. IEEE Transactions on Industrial Electronics, 2018, 65(3): 2199-2211.

    [7] Song W, Hou N, Wu M. Virtual Direct Power Control Scheme of Dual Active Bridge DC-DC Converters for Fast Dynamic Response. IEEE Transactions on Power Electronics, 2018, 33(2): 1750-1759.

    [6] Song W, Deng Z, Wang S, Feng X. A Simple Model Predictive Power Control Strategy for Single-phase PWM Converters with Modulation Function Optimization. IEEE Transactions on Power Electronics, 2016, 31(7): 5279 - 5289.

    [5] Ma J, Song W*, Feng X, Zhao J. Power Calculation for Direct Power Control of Single Phase Three Level Rectifiers without Phase Lock Loop. IEEE Transactions on Industrial Electronics, 2016, 63(5): 2871-2882.

    [4] Hou N, Song W*, Wu M. Minimum-Current-Stress Scheme of Dual Active Bridge DC-DC Converter with Unified-phase-shift Control. IEEE Transactions on Power Electronics, 2016, 31(12): 8552-8561.

    [3] Song W, Jiao S, Li Y W, Wang J and Huang J. High-Frequency Harmonic Resonance Suppression in High-Speed Railway through Single-phase Traction Converter with LCL Filter. IEEE Transactions on Transportation Electrification, 2016, 2(3): 347-356.

    [2] Song W, Ma J, Zhou L, Feng X. Deadbeat Predictive Power Control of Single Phase Three Level Neutral-Point-Clamped Converters Using Space-Vector Modulation for Electric Railway Traction. IEEE Transactions on Power Electronics, 2016, 31(1): 721-732.

    [1] Song W, Feng X, Smedley K M. A Carrier-Based PWM Strategy with the Offset Voltage Injection for Single-Phase Three-Level Neutral-Point-Clamped Converters. IEEE Transactions on Power Electronics, 2013, 28(3): 1083-1095.

     

    —————————————IET Journals————————————————————

    [10] Liu B, Song W, Chen J, Feng X. Model predictive power control for grid-connected AC-DC converters with trajectory optimization of the modulated voltage vector. IET Power Electronics, 2020, 13(10): 2060-2068.

    [9] An F, Song W*, Yang K, Luo S, Feng X. Optimized Power Control and Balance Scheme for the Output Parallel Dual-Active-Bridge DC-DC Converters in Power Electronic Traction Transformer. IET Power Electronics, 2019, 12(9): 2295 - 2303.

    [8] An F, Song W*, Yang K, Nou N, Ma J. Improved Dynamic Performance of Dual Active Bridge DC-DC Converters Using Model Predictive Control Scheme. IET Power Electronics, 2018, 11(11): 1756-1765.

    [7] Liu B, Song W*, Ma J, Feng X, and Li W. Dynamic performance improvement of single-phase PWM converters with power hysteresis control scheme. IET Power Electronics, 2018, 11(12): 1894-1902.

    [6] Xue C, Song W*, Feng X. Finite Control-Set Model Predictive Current Control of Five-phase Permanent-Magnet Synchronous Machine Based on Virtual Voltage Vectors. IET Electric Power Application, 2017, 11(5): 836-846.

    [5] Cui H, Song W*, Ge X, and Feng X. High-frequency Resonance Suppression of High-speed Railways in China. IET Electrical Systems in Transportation, 2016, 6(2): 88-95.

    [4] Wang S, Song W*, Zhao J, Feng X. A Hybrid Single-Carrier-Based PWM Scheme for Single-Phase Three-Level NPC Grid-side Converters in Electric Railway Traction. IET Power Electronics, 2016, 9(13): 2500-2509.  

    [3] Cui H, Song W, Fang H, Ge X, and Feng X. Resonant Harmonic Elimination PWM-Based High-Frequency Resonance Suppression of High-Speed Railways. IET Power Electronics, 2015, 8(5): 735-742.  

    [2] Fang H, Feng X, Song W, Ge X, Ding R. Relationship between two-level space-vector pulse-width modulation and carrier-based pulse-width modulation in the over-modulation region. IET Power Electronics, 2014, 7(1): 189-199.  

    [1] Song W, Wang S, Xiong C, Ge X, Feng X. Single Phase Three-level SVPWM Algorithm for Grid-side Railway Traction Converter and Its Relationship of Carrier-based PWM. IET Electrical Systems in Transportation, 2014, 4(3): 78-87.

     

    ——————————中国电机工程学报—————————————————

     

    [37] 宋文胜, 陈津辉*, 刘碧, 蒋蔚. 单相级联H桥整流器简化模型预测功率控制.中国电机工程学报. 2021, 已录用

    [36] 宋文胜, 郭永琪, 余彬*, 谢宗楚, 李建新. 五相永磁同步电机全速度范围占空比优化模型预测电流控制.中国电机工程学报. 2021, 已录用

    [35] 李佳耀, 宋文胜*, 刘碧, 余彬, 冯加旭. 低转矩脉动和共模电压的永磁同步电机模型预测脉冲序列控制.中国电机工程学报. 2021, 已录用

    [34] 冯凌, 付建国, 廖丽诚, 文宇良, 宋文胜. 一种改进的永磁同步牵引电机低开关频率模型预测直接转矩控制策略.中国电机工程学报. 2021, 已录用

    [33] 彭林,马磊,刘浩然,宋文胜. 单相PWM整流器H∞混合灵敏度电流控制.中国电机工程学报. 2020, 已录用

    [32] 余彬, 宋文胜*, 冯加旭, 宋玉明, 唐涛. 基于虚拟电压矢量的五相电压源逆变器空间矢量调制算法.中国电机工程学报. 2020, 40(1): 212-221.

    [31] 宋文胜, 蒋蔚, 刘碧, 邓睿. 单相级联H桥整流器简化模型预测电流控制. 中国电机工程学报. 2019, 39(4):1127-1137.

    [30] 宋玉明, 宋文胜*,余彬. 基于单周期控制的牵引电机拍频抑制算法数字化实现.中国电机工程学报. 2019, 39(10):3007-3015.

    [29] , 宋文胜*, 杨柯欣. 基于扩展相移的双有源全桥DC-DC变换器多目标优化控制方法, 中国电机工程学报. 2019, 39(3):822-831.

    [28] 武雪松, 宋文胜*, . 基于虚拟电压矢量集占空比优化的五相永磁同步电机直接转矩控制算法. 中国电机工程学报. 2019, 39(3):857-867.

    [27] 余彬, 宋文胜*, 薛诚, 武雪松, 唐涛. 一种基于优化占空比的五相永磁同步电机直接转矩控制算法. 中国电机工程学报. 2019, 39(19):5857-5866.

    [26] 刘碧, 冯晓云, 邓睿, 夏文婧, 宋文胜. 基于模型参考自适应的单相脉冲整流器无网压传感器控制方法. 中国电机工程学报, 2019, 39(20):6065-6074.

    [25] , 宋文胜*, 杨柯欣. 电力电子变压器的双有源全桥DC-DC变换器模型预测控制及其功率均衡方法. 中国电机工程学报. 2018, 38(13): 3921-3929.

    [24] 韩坤, 孙晓, 刘秉, 宋文胜, 冯晓云. 一种永磁同步电机矢量控制SVPWM死区效应在线补偿方法. 中国电机工程学报. 2018, 38(2): 620-627.

    [23] 武明义, 侯聂, 宋文胜*, 蒋威. 独立输入并联输出全桥隔离DC-DC变换器直接功率平衡控制. 中国电机工程学报. 2018, 38(5): 1329-1337.

    [22] 杨柯欣, 宋文胜*, , . 双向有源全桥DC-DC变换器电流源模式的快速动态响应控制方法. 中国电机工程学报. 2018, 38(8): 2439-2447.

    [21] 碧,宋文胜*, 孙可心, 余彬, 李水昌. 基于调制电压椭圆轨迹优化的单相脉冲整流器模型预测电流控制. 中国电机工程学报. 2018, 38(17): 5177-5188.

    [20] , 宋文胜*. 基于虚拟信号反馈算法的单相PWM整流器DQ电流解耦控制. 中国电机工程学报. 2018, 38(15): 4504-4513.

    [19] 宋文胜, 杨柯欣, , . 基于输入电压前馈的双向有源桥式DC-DC变换器虚拟功率控制方法. 中国电机工程学报. 2018, 38(22): 6491-6502.

    [18] 薛诚, 宋文胜*, 冯晓云. 双重d-q空间下五相电压源逆变器空间矢量脉宽调制死区效应分析与补偿.中国电机工程学报. 2017, 37(9):2667-2676.

    [17] 薛诚, 宋文胜*, 武雪松, 冯晓云. 考虑去磁效应的五相永磁同步电机优化开关表直接转矩控制算法. 中国电机工程学报. 2017, 37(19):5774-5784.

    [16] , 宋文胜*, 武雪松, 冯晓云.无差拍优化五相永磁同步电机有限集模型预测转矩控制算法. 中国电机工程学报. 2017, 37(23):7014-7023.

    [15]   , 宋文胜*, 武明义. 双向全桥DC-DC变换器的负载电流前馈控制方法.中国电机工程学报. 2016, 36(9): 2478-2485.

    [14] 宋文胜, , 武明义, 冯晓云. 双向全桥隔离DC/DC 变换器最小峰值电流及其虚拟功率控制方法. 中国电机工程学报. 2016, 36(18): 4990-4998.

    [13] , 宋文胜*, 王顺亮. 全桥隔离DC/DC变换器相移控制归一化及其最小回流功率控制. 中国电机工程学报. 2016, 36(2): 499-506.

    [12] 马俊鹏, 宋文胜*, 冯晓云. 单相三电平脉冲整流器模型预测直接功率控制. 中国电机工程学报. 2016, 36(4): 1098-1105.

    [11] 邓知先, 宋文胜*, 曹梦华. 单相PWM整流器模型预测电流控制算法. 中国电机工程学报. 2016, 36(11): 2996-3004.

    [10] , 宋文胜*, 冯晓云. 五相永磁同步电机多目标优化直接转矩控制算法.中国电机工程学报. 2016, 36(6): 1695-1704.

    [9] 范文进, 郑琼林, 杨中平, 林飞, 宋文胜, DO Viet Dung. 一种中高速区转矩优化的异步电机直接转矩控制算法.中国电机工程学报. 2016, 36(1): 240-249.

    [8] 方辉, 吴瑕杰, 宋文胜, 冯晓云. 过调制区内三电平SVPWMCBPWM算法的统一性研究. 中国电机工程学报. 2015, 35(8): 1993-2001.

    [7] 马俊鹏, 宋文胜, 王顺亮, 冯晓云. 单相三电平脉冲整流器无差拍预测直接功率控制. 中国电机工程学报. 2015, 35(4): 935-943.

    [6] 马俊鹏, 宋文胜, 冯晓云. 单相三电平脉冲整流器无锁相环直接功率控制. 中国电机 工程学报. 2015, 35(7): 1723-1731.

    [5] 王顺亮, 宋文胜,冯晓云. 基于电压补偿分量注入的单相级联H桥整流器载波调制与电容电压平衡方法. 中国电机工程学报. 2015, 35(12): 3117-3123.

    [4] , 宋文胜. 全桥隔离DC/DC变换器的三重相移控制及软启动控制方法. 中国电机工程学报. 2015, 35(23): 6113-6121.

    [3] 苟斌, 冯晓云, 宋文胜, 韩坤, 葛兴来. 牵引变流器-电机拍频现象及其抑制方法. 中国电机工程学报, 2013,33(9): 55-63.

    [2] 方辉, 冯晓云, 葛兴来, 宋文胜. 过调制区内两电平SVPWMCBPWM算法的内在联系研究. 中国电机工程学报, 2012,32(8): 23-30.

    [1] 宋文胜, 冯晓云. 基于零序电压分量注入的单相三电平NPC整流器脉宽调制方法. 中国电机工程学报. 2011, 31(36)16-24.