教师简介

杨鸣，博士（后），副教授，博士生导师，IEEE Senior Member，IEEE Trans. Power Delivery编辑。主要研究方向为交直流混联电网电磁暂态分析，包括变压器类装备电磁暂态建模与应用、直流断路器设计与暂态特性分析、直流变压器电磁暂态建模与分析、交直流混联电网电磁暂态特性分析与防护等。

主持国家自然科学基金2项，国家重点研发计划子课题1项，重庆市博士后基金1项，南方电网公司和中国石化公司科技项目2项；以主要研究人员参研国家自然科学基金重点项目1项（排名2）、面上项目2项，973课题1项，国家重点研发计划课题1项。

近五年，共发表论文30余篇，其中以第一作者或通讯作者身份在IEEE Trans Ind Electron, Int J Elect Power Energy Syst和IEEE Trans Power Del三本国际期刊（一区）上发表论文13篇（其中一区IEEE Trans论文8篇），以第一作者身份在IEEE Trans Power Del上发表为数不多的连载论文2篇（Part I和Part II）；申请或获权国家发明专利20余项，获软件著作权1项。

系高电压与绝缘技术系“过电压与接地技术”团队骨干。团队负责人：司马文霞，教授。团队实行“统一招生、联合指导”培养模式，欢迎广大考生报考！

课题组学术氛围浓厚，师生长期通过“周例会”共同探讨学术问题、解决学术困难、梳理学术思路、总结学术成果，有兴趣同学可以申请线上或线下试听，提前体验学术氛围。

邮箱：cqucee@cqu.edu.cn

网页：https://scholar.google.com/citations?user=IKffrBsAAAAJ&hl=en

教育经历：

1. 2009/09-2014/06，重庆大学，电气工程，博士（推免直攻博），

2. 2005/10-2009/06，重庆大学，电气工程与自动化，学士

工作经历：

1. 2017/09-现在，重庆大学，电气工程学院，副教授

2. 2016/12-2018/12，纽约大学，Tandon School of Engineering，博士后

3. 2014/12-2017/08，重庆大学，电气工程学院，讲师

4. 2014/10-2018/01，重庆大学，自动化学院，师资博士后

学术兼职：

1. 2020/04-现在，IEEE Transactions on Power Delivery、IEEE Power Engineering Letters编辑 （Editor）

2. 2017/06-现在，CIGRE C4.45工作组、IEEE P2426标准工作组成员

主要科研项目：

1. 国家自然科学基金面上项目，51977018，高频变压器高矩形比铁心磁化时空非线性与绕组宽频特性的耦合建模，2020/01-2023/12，在研，主持

2. 国家重点研发计划子课题，2017YFB0902701，“特高压设备及其组成系统宽频电磁暂态特性”之子课题，2017/07-2020/12，在研，主持

3. 国家自然科学基金青年项目，51507019，典型暂态过电压下变压器铁芯磁化动力学特性与计及磁频散和磁后效的暂态磁滞模型，2016/01-2018/12，结题（优秀），主持

4. 国家自然科学基金重点项目，51837002，电网大规模实测过电压统计分布特性及其对典型绝缘影响的基础研究，2019/01-2023/12，在研，参研（排名2）

5.  973课题，2015CB251003，电流转移与电能耗散中的电介质绝缘特性及其演变规律，2015/01-2019/12，结题，参研

代表性论文（近五年）：

*=通讯作者

[1] Wenxia Sima, Binyang Zou, Ming Yang*, and Francisco de Leόn. New method to measure deep-saturated magnetizing inductances for dual reversible models of single-phase two-winding transformers. IEEE Transactions on Energy Conversion, 2020. Early Access.

[2] Wenxia Sima, Daixiao Peng, Ming Yang*, Potao Sun, Binyang Zou, Zhao Xiong. Reversible wideband hybrid model of two-winding transformer including the core nonlinearity and EMTP implementation. IEEE Transactions on Industrial Electronics, 2020. Early Access.

[3] Zhengzheng Fu, Wenxia Sima, Ming Yang*, Potao Sun, Tao Yuan, Xiaofeng Wang, and Long Yang. A mutual-inductance-type fault current limiter in MMC-HVDC systems. IEEE Transactions on Power Delivery, 2020. Early Access.

[4] Ming Yang*, Digvijay Deswal, and Francisco de Leόn. Mitigation of half-cycle saturation of adjacent transformers during HVDC monopolar operation - Part II: detecting zero-sequence fault currents. IEEE Transactions on Power Delivery, 2020, 35(1): 16–24.

[5] Ming Yang*, Digvijay Deswal, and Francisco de Leόn. Mitigation of half-cycle saturation of adjacent transformers during HVDC monopolar operation - Part I: mitigation principle and device design. IEEE Transactions on Power Delivery, 2019, 34(6): 2232–2239.

[6] Wenxia Sima, Daixiao Peng, Ming Yang*, Yonglai Liu, Pan Duan, Jun Deng, and Hai Qian. Low-frequency model for single-phase transformers based on the three-component Preisach model considering deep saturation. International Journal of Electrical Power & Energy Systems, 2019, 110: 107–117.

[7] Wenxia Sima, Zhengzheng Fu, Ming Yang*, Tao Yuan, Potao Sun, Xue Han, and Yan Si. A novel active mechanical HVDC breaker with consecutive interruption capability for fault clearances in MMC-HVDC systems. IEEE Transactions on Industrial Electronics, 2019, 66(9): 6979–6989.

[8] Wenxia Sima, Han Zhang, Ming Yang*, Tao Yuan, Potao Sun, Qinzhu Chen, Hailong Zhao. A framework for automatically cleansing overvoltage data measured from transmission and distribution systems. International Journal of Electrical Power & Energy Systems, 2018, 102: 381–392.

[9] Ming Yang*, Reza Kazemi, Saeed Jazebi, Digvijay Deswal, and Francisco de Leόn. Retrofitting the BCTRAN transformer model with non-linear magnetizing branches for the accurate study of low-frequency deep saturating transients [J]. IEEE Transactions on Power Delivery, 2018. 33(5): 2344–2353.

[10] Wenxia Sima, Mi Zou, Ming Yang*, Daixiao Peng, Yonglai Liu. Saturable reactor hysteresis model based on Jiles–Atherton formulation for ferroresonance studies. International Journal of Electrical Power & Energy Systems, 2018, 101: 482–490.

[11] Xue Han, Wenxia Sima, Ming Yang*, Licheng Li, Tao Yuan, Yan Si. Transient characteristics under ground and short-circuit faults in a ±500 kV MMC-based HVDC system with hybrid DC circuit breakers. IEEE Transactions on Power Delivery, 2018, 33(3): 1378–1387.

[12] Ming Yang, Wenxia Sima*, Lijun Chen, Pan Duan, Potao Sun, Tao Yuan. Suppressing ferroresonance in potential transformers using a model-free active-resistance controller. International Journal of Electrical Power & Energy Systems, 2018, 95: 384–393.

[13] Ming Yang*, Wenxia Sima, Pan Duan, Mi Zou, Daixiao Peng, Qing Yang, Qichang Duan. Electromagnetic transient study on flexible control processes of ferroresonance. International Journal of Electrical Power & Energy Systems, 2017, 93: 194–203.

[14] Ming Yang*, Wenxia Sima, Qing Yang, Jianbiao Li, Mi Zou, Qichang Duan. Non-linear characteristic quantity extraction of ferroresonance overvoltage time series. IET Generation, Transmission & Distribution, 2017, 11(6): 1427–1433.

[15] Ming Yang, Wenxia Sima*, Xue Han, Rong Wang, Chilong Jiang, Wenqi Mao, Potao Sun. Failure analysis and maintenance of a surge capacitor on the neutral bus in a ±500 kV HVDC converter station. IET Renewable Power Generation, 2016, 10(6): 852–860.