王牌
时间:2023-05-29
浏览:3975
基本信息
邮箱:paiwang@whu.edu.cn
工作地点:武汉大学卫星导航定位技术研究中心,武汉市洪山区珞喻路129号,430079
工作经历
2023.06-至今 武汉大学,卫星导航定位技术研究中心,特聘研究员
2021.07-2023.05 上海交通大学,电子信息与电气工程学院,长聘教轨副教授
2018.04-2021.05 美国科罗拉多大学博尔德分校,博士后,合作导师:Jade Morton教授
教育经历
2012.09-2018.03 工学博士,北京理工大学,信息与电子学院
专业:信息与通信工程
导师:吴嗣亮教授
研究方向:卫星导航抗干扰
2015.11-2016.11 联合培养,澳大利亚新南威尔士大学,电气工程与通信学院
导师:Andrew G. Dempster教授
2008.09-2012.06 工学学士,北京理工大学,信息与电子学院
专业:信息工程
研究项目
2023-2025. 国家自然科学基金青年基金,基于小区间干扰抑制和密集多径估计的城市环境用户侧移动通信定位信号处理方法,在研,主持
2019-2020 美国企业创新研究项目,Networked PNT solution for GPS-denied navigation,完成,参与
2015-2016 澳大利亚研究基金会项目,Protecting critical transport infrastructure using hybrid approaches for interference and spoofer detection and localization,完成,参与
学术成果
期刊论文
1. Y. Lee, P. Wang, and B. Park, “Nonlinear regression-based GNSS multipath dynamic map construction and its application in deep urban areas”, IEEE Transactions on Intelligent Transportation Systems, 2023, 24(5):5082-5093.
2. P. Wang and Y. Morton, “Impact analysis of inter-cell interference in cellular networks for navigation applications,” IEEE Transactions on Aerospace and Electronic Systems, 2023, 59(1):685-694.
3. P. Wang, Y. Wang, and Y. Morton, “Signal tracking algorithm with adaptive multipath mitigation and experimental results for LTE positioning receivers in urban environments,” IEEE Transactions on Aerospace and Electronic Systems, 2022, 58(4):2779-2795.
4. P. Wang and Y. Morton, “Performance comparison of time-of-arrival estimation techniques for LTE signals in realistic multipath propagation channels,” NAVIGATION, 2020, 67(4):691-712.
5. P. Wang and Y. Morton, “Multipath estimating delay lock loop for LTE signal TOA estimation in indoor and urban environments,” IEEE Transactions on Wireless Communications, 2020, 19(8):5518-5530.
6. P. Wang and Y. Morton, “Efficient weighted centroid technique for crowdsourcing GNSS RFI localization using differential RSS,” IEEE Transactions on Aerospace and Electronic Systems, 2020, 56(3):2471-2477.
7. P. Wang, Y. Wang, E. Cetin, A. G. Dempster, and S. Wu, “Time-frequency jammer mitigation based on Kalman filter for GNSS receivers,” IEEE Transactions on Aerospace and Electronic Systems, 2019, 55(3):1561-1567.
8. P. Wang, Y. Wang, E. Cetin, A. G. Dempster, and S. Wu, “GNSS jamming mitigation using adaptive-partitioned subspace projection technique,” IEEE Transactions on Aerospace and Electronic Systems, 2019, 55(1):343-355.
9. P. Wang, E. Cetin, A. G. Dempster, Y. Wang, and S. Wu, “Improved characterization of GNSS jammers using short-term time-frequency Renyi entropy,” IEEE Transactions on Aerospace and Electronic Systems, 2018, 54(4):1918-1930.
10. P. Wang, E. Cetin, A. G. Dempster, Y. Wang, and S. Wu, “GNSS interference detection using statistical analysis in the time-frequency domain,” IEEE Transactions on Aerospace and Electronic Systems, 2018, 54(1):416-428.
11. P. Wang, E. Cetin, A. G. Dempster, Y. Wang, and S. Wu, “Time frequency and statistical inference based interference detection technique for GNSS receivers,” IEEE Transactions on Aerospace and Electronic Systems, 2017, 53(6):2865-2876.
12. P. Wang, Y. Wang, X. Yu, and S. Wu, “Performance comparison of code discriminators in the presence of CW interference,” Wireless Personal Communications, 2016, 89(2):405-426.
13. P. Wang, Y. Wang, and S. Wu, “A modified code tracking loop based on dual structure,” Science China Information Sciences, 2015, 58(8):1-10.
14. Y. Wang, Y. Luo, P. Wang, and S. Wu, “A novel joint navigation state error discriminator based on iterative maximum likelihood estimation,” Science China Information Sciences, 2015, 58(12):1-14.
15. Y. Luo, Y. Wang, S. Wu, and P. Wang, “Multipath effects on vector tracking algorithm for GNSS signal,” Science China Information Sciences, 2014, 57(10):1-13.
会议论文
1. A. Brevick, K. Strandjord, and P. Wang, “Evaluating navigation augmentation with LTE in the urban signal environment”, in Proceedings of ION ITM 2023, Long Beach, CA, USA, Jan. 2023, 1154-1168.
2. P. Wang and D. He, “Performance evaluation of information theoretic criteria-based path number estimators for cellular-based positioning with dense multipath,” in Proceedings of ION GNSS+ 2022, Denver, CO, USA, Sep. 2022, 2464-2477.
3. K. Strandjord, Y. Morton, and P. Wang, “Evaluating the urban signal environment for GNSS and LTE signals,” in Proceedings of ION GNSS+ 2021, St. Louis, MO, USA, Sep. 2021, 2166-2182.
4. P. Wang, Y. Wang, and Y. Morton, “Characterization and impact analysis of radio frequency interference for GNSS reflectometry,” in IEEE IGARSS 2020, Virtual, Oct. 2020, 6190-6193.
5. P. Wang and Y. Morton, “Carrier phase tracking architecture for positioning in LTE networks under channel fading conditions,” in Proceedings of ION GNSS+ 2020, Virtual, Sep. 2020, 2605-2617.
6. P. Wang and Y. Morton, “Improved time-of-arrival estimation algorithm for cellular signals in multipath fading channels,” in 2020 IEEE/ION PLANS, Portland, OR, USA, Apr. 2020, 1358-1364.
7. P. Wang and Y. Morton, “Performance comparison of time-of-arrival estimation techniques for LTE signals in realistic multipath propagation channels,” in Proceedings of ION GNSS+ 2019, Miami, FL, USA, Sep. 2019, 2241-2253.
学术兼职
●《GPS Solutions》编委
●《Satellite Navigation》青年编委
●《中国惯性技术学报》青年编委
●ION GNSS+ 2019、2020、2023会议分会主席
●ION Pacific PNT Meeting 2019、ION GNSS+ 2020、2021最佳论文奖委员会委员
获奖与荣誉
●国家留学基金委联合培养博士研究生奖学金,2015
●北京市优秀毕业生,2012
●国家奖学金,2011
受邀报告
●2023.04, the 13th China Satellite Navigation Conference, CSNC-ION joint panel, Integrated/alternative techniques for urban high-accuracy positioning, Beijing
●2022.01, The Hong Kong Polytechnic University, AAE Research Seminar Series, LTE cellular receiver design and signal processing for urban navigation, Online
●2019.10, Stanford University, the 13th Annual PNT Symposium, An efficient method for crowdsourcing GNSS RFI localization, San Francisco, CA, USA
●2019.05, Massachusetts Institute of Technology, Women in Aerospace Symposium, LTE-based positioning technologies for challenging environments, Cambridge, MA, USA
●2016.11, University of New South Wales, ACSER Seminar Series, Interference detection, characterization, and mitigation techniques for GNSS receivers. Sydney, NSW, Australia