李政颖
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信息工程学院博∕硕士导师信息表 |
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姓 名: |
李政颖 |
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性 别: |
男 |
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职 称: |
教授、博导 |
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电 话: |
15807150968 |
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邮 箱: |
zhyli@whut.edu.cn |
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通讯地址: |
武汉理工大学 湖北省武汉市珞狮路122号430070 |
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研究领域: |
光纤传感、智能感知 |
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工作经历: |
2025/10 ~ 至今 武汉理工大学,副校长 2021/12 ~ 2025/09 武汉理工大学,信息工程学院,院长 2010/07 ~ 至今 武汉理工大学信息工程学院,讲师、副教授、教授 2016/07 ~ 2017/07 渥太华大学,访问学者 |
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教育经历: |
2007/09 ~ 2010/06 武汉理工大学,通信与信息系统,博士 2009/01 ~ 2010/02 美国弗吉尼亚理工大学,电子工程,联合培养博士 2004/09 ~ 2007/06 武汉理工大学,控制理论与控制工程,硕士 1999/09 ~ 2003/06 武汉理工大学,自动化,学士 |
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个人简介: |
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国家高层次人才项目获得者,武汉理工大学信息工程学院教授、博士生导师,武汉理工大学副校长。长期从事大容量、长距离、智能化分布式光纤传感网络的器件制备、信息获取与工程应用研究。 主持国家重点研发计划项目(2024)、国家自然科学基金区域联合基金(重点)项目(2024)、国家自然科学基金重点项目(2018)、国家自然科学基金面上项目(2023、2016)等国家级及省部级科研项目10余项;主持军委科技委国防科技创新特区163专项项目2项。 发表100余篇SCI收录论文,其中以第一作者/通讯作者在Photonics Research、Journal of Lightwave Technology等国际权威学术期刊发表论文74篇。申请中国发明专利120余项,其中获授权90余项;获授权美国发明专利4项。 获全国五一劳动奖章(2024),OFS-China第一届光纤传感优秀青年人才奖(2024),湖北省科学技术奖技术发明一等奖(2025,排1),中国建筑材料科学技术奖技术进步一等奖(2024,排1)、技术发明一等奖(2019,排2),湖北专利奖金奖(2021,排1),中国专利优秀奖(2021,排1)。 |
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主要在研项目: |
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国家重点研发计划项目“基于光纤传感网络的商用飞机智能复合材料”(2024YFF0508400),主持,2024/12 ~ 2029/11 国家自然科学基金区域联合(重点)项目“大范围高分辨率全光纤分布式超声无损检测及成像的理论与方法研究”(U24A20306),主持,2025/01 ~ 2028/12 国家自然科学基金面上项目“微腔阵列三分量振动分布式传感方法研究”(62275205),主持,2023/01 ~ 2026/12 国家自然科学基金重点项目“智能轨道交通安全监测光纤传感基础研究”(61735013),主持,2018/01 ~ 2022/12 国家自然科学基金面上项目“基于色散效应的大规模全同光栅传感网络高速解调新方法的研究”(61575149),主持,2016/01 ~ 2019/12 国家自然科学基金青年科学基金项目“基于共轭干涉的光学气体传感理论与方法的研究”(61205072),主持,2013/01 ~ 2015/12 中央军委国防科技创新特区163计划项目“分布式光致超声无损探伤智能感知技术”(18-163-00-TS-001-001-44),主持,2019/07 ~ 2022/06 中央军委国防科技创新特区163计划项目“基于XXX分布式传感技术”(19-163-13-ZT-021-003-10),主持,2019/07 ~ 2020/06 湖北省自然科学基金创新群体项目“大规模光纤水听器智能传感网络”(2022CFA034),主持,2022/10 ~ 2025/09 湖北省自然科学基金杰出青年项目“基于微腔阵列光纤的全分布式传感方法研究”(2018CFA056),主持,2018/03 ~ 2021/03 |
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科研获奖: |
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2025 湖北省科学技术奖技术发明一等奖(排1) 2024 中国建筑材料科学技术奖技术进步一等奖(排1) 2021 湖北专利奖金奖(排1) 2021 中国专利优秀奖(排1) 2018 中国建筑材料科学技术奖技术发明一等奖(排2) |
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| 代表性论文(第一作者\通讯作者): | |||
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1. J. Li et al., “Multifunctional MXene-based anti-corrosion coatings with fiber-triggered ultrasonic emission for in-situ structural integrity monitoring,” Composites Part B: Engineering, vol. 309, p. 113104, Jan. 2026. 2. Y. Wu et al., “Low-frequency fiber-optic optoacoustic transducer arrays for large-area high-precision online non-destructive testing,” Ultrasonics, vol. 154, p. 107680, Oct. 2025. 3. Z. Tang, X. Gui, Z. Li, F. Zeng, and S. Li, “An impact damage monitoring method for composite materials based on strain correlation of interlayers with optical fiber sensors,” Composite Structures, vol. 368, p. 119288, Sept. 2025. 4. C.-J. Wang, X. Gui, X.-L. Fu, Y.-M. Wang, C.-Y. He, and Z.-Y. Li, “CFBG enhanced distributed acoustic sensing covering millihertz to kilohertz band,” Optics & Laser Technology, vol. 184, p. 112448, June 2025. 5. X. Gui, F. Zeng, J. Gao, X. Fu, and Z. Li, “Detection of aircraft wing icing and de-icing by optical fiber sensing with FBG array,” Measurement, vol. 247, p. 116748, Apr. 2025. 6. Z. Li, C. Wang, X. Fu, W. Li, X. Gui, and J. Shi, “A phase unwrapping algorithm for high dynamic range distributed acoustic sensing with signal fidelity,” Meas. Sci. Technol., vol. 36, no. 3, p. 035116, Mar. 2025. 7. B. He, X. Fu, X. Gui, and Z. Li, “High spatial resolution and dynamic OFDR-based method for detecting ship structural response,” Meas. Sci. Technol., vol. 36, no. 3, p. 035214, Mar. 2025. 8. T. Zhao, Z. Li, W. Liu, X. Fu, Y. Zhou, and L. Zhou, “Unconstrained respiratory event detection using a flexible tactile sensor,” IEEE Sensors J., vol. 24, no. 19, pp. 30095-30103, Oct. 2024. 9. Y. Wu, X. Fu, J. Li, P. Zhang, H. Wang, and Z. Li, “All-fiber photoacoustic system for large-area nondestructive testing,” Structural Health Monitoring, vol. 23, no. 4, pp. 2123-2134, July 2024. 10. H. Jin et al., “Accelerated reconstruction of ZIF-67 with significantly enhanced glucose detection sensitivity,” Nano Res., vol. 17, no. 6, pp. 4737-4743, June 2024. 11. H. Guo et al., “The role of a kind of DID defect-open tear defect in the recording of gratings using excimer lasers in low-loss optical fibers,” J. Lightwave Technol., vol. 42, no. 5, pp. 1645-1650, Mar. 2024. 12. X. Fu, Y. Gou, Y. Zou, and Z. Li, “Robust acoustic impedance monitoring based on forward stimulated Brillouin scattering in an aluminum-coated optical fiber,” Opt. Eng., vol. 63, no. 03, p. 031007, Mar. 2024. 13. J. Zhan et al., “Non-contact assessment of cardiac physiology using FO-MVSS-based ballistocardiography: a promising approach for heart failure evaluation,” Sci Rep, vol. 14, no. 1, p. 3269, Feb. 2024. 14. H. Jin et al., “Fast and in-depth reconstruction of two-dimension cobalt-based zeolitic imidazolate framework in glucose oxidation processes,” ACS Appl. Mater. Interfaces, vol. 16, no. 6, pp. 8151-8157, Feb. 2024. 15. Z. Li, X. Tang, T. Zhao, K. Chen, and T. Zhang, “Highly sensitive skin-like wearable optical sensor for human physiological signals monitoring,” Optical Fiber Technology, vol. 82, p. 103652, Jan. 2024. 16. T. Zhao, X. Fu, Y. Zhou, J. Zhan, K. Chen, and Z. Li, “Noncontact monitoring of heart rate variability using a fiber optic sensor,” IEEE Internet Things J., vol. 10, no. 17, pp. 14988-14994, Sept. 2023. 17. F. Liu, B. Xu, H. Wang, J. Jiang, S. Li, and Z. Li, “Online long-distance monitoring of subway vibration reduction effect using ultra-weak fiber Bragg grating arrays,” Measurement, vol. 217, p. 113057, Aug. 2023. 18. Z. Li et al., “A high-performance fiber-optic hydrophone for large scale arrays,” J. Lightwave Technol., vol. 41, no. 13, pp. 4201-4210, July 2023. 19. X. Gui et al., “Distributed optical fiber sensing and applications based on large-scale fiber Bragg grating array: review,” J. Lightwave Technol., vol. 41, no. 13, pp. 4187-4200, July 2023.
20. X. Gui, S. He, Y. Wang, X. Fu, Y. Guo, and Z. Li, “Anti-noise UWFBG-array enhanced DAS system using double-pulse-based time-domain adaptive delay interference,” Opt. Lett., vol. 48, no. 7, pp. 1814-1817, Apr. 2023. |
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