1. 中国电波传播研究所，工程师，高级工程师（1992年7月- 1998年9月）

2. 赫尔辛基工业大学博士，博士后（1998年10月 - 2004年10月）

3. 赫尔辛基工业大学高级研究员（2003年1月-2004年10月）

4. 芬兰Elektrobit（EB）高级工程师，专家，高级专家（2004年11月 - 2012年1月）

5. 华北电力大学教授，博士生导师（2012年2月 -）

6. 电气与电子工程学院，信息与通信学科责任教授（2019年 -）

7. 中国电子学会会士（2018 -）



  赵雄文，华北电力大学教授，博士生导师，电气与电子工程学院弱电学科责任教授。中国电子学会会士，电波传播专委会委员。中国通信学会高级会员，能源互联网专委会委员，IEEE Senior Member。2002年获赫尔辛基工业大学（现芬兰阿尔托大学）无线电工程博士学位。

  主要从事5G和后5G无线通信、电力系统通信和泛在电力物联网领域的研究和教学工作。近五年主持国家自然科学基金面上项目2项，主持北京市基金重点子课题和北京市科委5G培育项目各1项，参加1项国家863项目，主持和完成10余项国家重点实验室纵向项目和企业横向项目。担任国家留学基金委和国家自然科学基金委重点基金等评审专家，国家5G高频组专家。

  发表学术论文150余篇，近60篇IEEE等期刊论文被SCI收录，担任多个IEEE国际和国内会议技术委员会和国际咨询委员会共主席，作过多次主题、特邀和专题报告。2014年获IEEE Vehicular Technology Society (VTS)：Neal Shepherd Memorial Best Propagation Paper Award。2018年获 IEEE第12届国际天线、传播和电磁理论会议最佳论文奖和华北电力大学首届“我身边的好老师”荣誉称号。

1. 国家自然科学基金，面向5G的毫米波时变信道建模与仿真技术研究, 2018/01 - 2021/12，58万元，主持。

2. 国家自然科学基金，M2M MIMO宽带无线信道模型及其传播特性和机理研究，2014/01- 2017/12，82万元，主持。

3. 北京市科学技术委员会5G培育项目，海量机器通信场景下的5G信道建模技术研究， 2018/01 - 2019/12，100万元，主持。

1. IEEE Vehicular Technology Society, 2014, Neal Shepherd Memorial Best Propagation Paper Award, 国际学术成果奖，3/5.

2. IEEE Antennas and Propagation Society, and Chinese Institute of Electronics, 2018, ISAPE Best Paper Award, 国际会议最佳论文奖，2/5.

3. 电子工业部，1998，微波传播实验与理论研究，科技进步三等奖，1/7.

[1] Xiongwen Zhao et al., Doppler Spectra for F2F Radio Channels with Moving Scatterers, IEEE Transactions on Antennas and Propagation, 2016, 64(9): 4107-4112. (SCI)

[2] Xiongwen Zhao et al., A Novel Full Path-Loss Model for a Street Crossing in Urban Microcells, IEEE Transactions on Antennas and Propagation, 2015(12): 5878-5883. (SCI)

[3] Xiongwen Zhao et al., Two-Cylinder and Multi-Ring GBSSM for Realizing and Modeling of Vehicle-to-Vehicle Wideband MIMO Channels, IEEE Transactions on Intelligent Transportation Systems, 2016, 17(10): 2787-2799. (SCI)

[4] Xiongwen Zhao et al., Propagation Characteristics for Wideband Outdoor Mobile Communications at 5.3 GHz, IEEE Journal on Selected Areas in Communications, 2002, 20(3): 507-514. (SCI )

[5] Xiongwen Zhao et al., Multipath Propagation Study Combining Diffraction and Reflection, IEEE Transactions on Antenna and Propagation, 2001, 49(8): 1204 -1209. (SCI)

[6] Xiongwen Zhao eta l., Characterization of Doppler Spectra for Mobile Communications at 5.3 GHz, IEEE Transactions on Vehicular Technology, 2003, 52(1): 14-23. (SCI )

[7] Xiongwen Zhao et al., Attenuation by Human Bodies at 26 and 39.5GHz Millimeter Wave Bands, IEEE Antennas and Wireless Propagation Letters, 2017, 16: 1229-1232. (SCI)

[8] Xiongwen Zhao et al., Correlations of Wideband Channel Parameters in Street Canyons at 2.45 and 5.25 GHz, IEEE Antennas & Wireless Propagation Letters, 2007, 6: 252-254. (SCI)

[9] Xiongwen Zhao et al., Pathloss Models for Urban Microcells at 5.3 GHz, IEEE Antennas & Wireless Propagation Letters, 2006: 152-154. (SCI)

[10] Xiongwen Zhao et al., Path-Loss Model Including LOS-NLOS Transition Regions for Indoor Corridors at 5GHz, IEEE Antennas & Propagation Magazine,2013, 55(3): 217-223. (SCI)

[11] Xiongwen Zhao et al., Comparisons of Channel Parameters and Models for Urban Microcells at 2 GHz and 5 GHz, IEEE Antennas and Propagation Magazine, 2015, 56(6): 260-276. (SCI)

[12] J. Kivinen, Xiongwen Zhao et al., Empirical Characterization of Wideband Indoor Radio Channel at 5.3 GHz, IEEE Transactions on Antenna and Propagation, 2001, 49(8): 1192-1203. (SCI )

[13] J. Zhang, Z. Zheng, J. Xie, Y. Zhang, Xiongwen Zhao, and G. Gui, 3D MIMO: Several Observations from 32 to Massive 256 Antennas Based on Channel Measurement, IEEE Communications Magazine, 2018, 56(2): 62-70. (SCI )

[14] S. Geng, J. Kivinen, Xiongwen Zhao et al., Millimeter-Wave Propagation Channel Characterization for Short-Range Wireless Communications,” IEEE Transactions on Vehicular Technology, 2009, 58(1): 3-13. (SCI )

[15] Z. Zhou, Y. Guo, Y. He, Xiongwen Zhao et al., Access Control and Resource Allocation for M2M Communications in Industrial Automation, IEEE Transactions on Industrial Informatics, 2019, 15(5): 3093-3103. (SCI)

[16] Xiongwen Zhao et al., Channel Measurements, Modeling, Simulation and Validation at 32 GHz in Outdoor Microcells for 5G Radio Systems, IEEE Access, 2017, 5: 1062-1072. (SCI)

[17] Xiongwen Zhao et al., Dimension Reduction of Channel Correlation Matrix Using CUR-Decomposition Techniques for 3-D Massive Antenna System, IEEE Access, 2018, 6: 3031-3039. (SCI)

[18] Xiongwen Zhao et al., A Dual-Band Frequency Reconfigurable MIMO Patch-Slot Antenna Based on Reconfigurable Microstrip Feedline , IEEE Access, 2018, 6: 41450- 41457. (SCI)

[19] Xiongwen Zhao et al., Single RF-Chain Beam Training for MU-MIMO Energy Efficiency and Information-Centric IoT Millimeter Wave Communications, IEEE Access, 2019, 7: 6597-6610,. (SCI)

[20] Xiongwen Zhao et al., A Link-Based Variable Probability Learning Approach for Partially Overlapping Channels Assignment on Multi-Radio Multi-Channel Wireless Mesh Information- Centric IoT Networks, IEEE Access, 2019, 7: 45137-45145. (SCI).

[21] Xiongwen Zhao et al., A Reconfigurable MIMO/UWB MIMO Antenna for Cognitive Radio Applications, IEEE Access, 2019, 7: 46739-46747. (SCI)

[22] Xiongwen Zhao et al., Measurements and Modeling for Indoor D2D Wideband MIMO Radio Channels at 5GHz, IET Communications, 2016, 10(14): 1839-1845. (SCI)

[23] Xiongwen Zhao et al., Approach for Modeling of Broadband Low-Voltage PLC Channels Using Graph Theory, IET Communications, 2018, 12(3): 1524-1530 . (SCI).

[24] Xiongwen Zhao et al., Modelling and comparison for low-voltage broadband power line noise using LS-SVM and wavelet neural networks, IET Communications, 2019, 13(2): 171-178. (SCI)

[25] Xiongwen Zhao et al., Path Loss Modification and Multi-User Capacity Analysis by Dynamic Rain Models for 5G Radio System in Millimeter Waves, IET Communications, 2019, 13(10): 1488-1496. (SCI)

[26] Xiongwen Zhao et al., Hybrid Precoding with Phase Shifter Reduction for 5G Massive Antenna Multi-User Systems in Millimeter Wave, IET Communications, 2019, DOI: 10.1049 /iet-com.2018.5920

[27] Xiongwen Zhao et al., Channel Sounding, Modeling and Characterization in a Large Waiting Hall of a High Speed Railway Station at 28 GHz, IET Microwaves, Antennas and Propagation, DOI: 10.1049/iet-map.2019.0354 .(SCI)

[28] Z. Zhou, H. Liao, Xiongwen Zhao et al., Reliable Task Offloading for Vehicular Fog Computing under Information Asymmetry and Information Uncertainty, IEEE Transactions on Vehicular Technology, 2019, DOI: 10.1109/TVT.2019.2926732. (SCI)

[29] Xiongwen Zhao et al., Neural Network and GBSM Based Time-Varying and Stochastic Channel Modeling for 5G Millimeter Wave Communications, China Communications, 2019, 16(6): 80-90. (SCI)

[30] X.Liang, Xiongwen Zhao et al., A Geometry-Based Scattering Model for Vehicle-to-Vehicle Wideband MIMO Relay-based Cooperative Channels, China Communications, 2016, 13(10): 1-10. (SCI)