2002/9~2006/6 中国人民解放军国防信息学院 通信工程专业学士
2006/9~2008/6 中国传媒大学 电磁场与微波技术专业硕士
2008/9~2013/10 北京交通大学 通信与信息系统专业博士
2011/5~2012/5 蒙特利尔工学院(École Polytechnique de Montréal) 访问学者
2011/9~2012/6 康考迪亚大学(Concordia University) 访问学者
2013/10~2016/12 北京交通大学通信与信息系统专业 讲师
2017/1至今 北京交通大学通信与信息系统专业 副教授
欢迎报考学硕与专硕,我的研究方向是微波与光学的交叉学科,主要涉及微波信号在光学中的处理和应用,大学阶段需要学习过通信原理相关知识即可,当然扎实的数学功底是必不可少的,现有在读硕士生4人,博士生1人,已毕业9人,每年名额有限,如久未回复速速联系其它导师。
2025年度入学的学生拟开展软件定义宽带调频雷达波形光子生成和时频重构方面的研究,本年度只有学硕名额
可推荐直博、硕博以及出国深造,如若志向是就业工作也十万分欢迎,毕业仍需要完成至少一篇小论文,技术方案和论文写作提供必要协助,需要掌握的专业工具:编程工具(Matlab等)、绘图工具(3dsMax)、文献管理工具(Endnote)
本科生课程:复变函数,光纤通信课程设计
研究生课程:光纤测量,微波光子学原理与应用
一作及通信作者论文如下:
[1] 赵韦晨, 李晶, 田成, 裴丽, and 宁提纲, “基于镜频抑制混频器的可调函数波形生成和共参调谐,” 光学学报, vol. 45, no. 3, pp. 0307001, 2025.
[2] Y. Jiang, J. Li, C. Tian, W. Zhao, L. Pei, and T. Ning, “Wideband microwave measurement based on single-channel mapping and image-rejection mixing,” Applied Optics, vol. 64, no. 8, pp. 2048-2056, 2025/03/10, 2025.
[3] 王雪辉, 李晶, 燕苗霞, 裴丽, 宁提纲, 郑晶晶, and 王建帅, “基于偏振复用调制的周期性光学任意波形生成方案,” 光通信技术, vol. 48, no. 3, pp. 95-101, 2024.
[4] 田成, 李晶, 赵韦晨, 裴丽, and 宁提纲, “基于DP-MZM调制交/直流功率检测的瞬时频率测量,” 光学学报, vol. 44, no. 21, 2024.
[5] M. Yan, J. Li, W. Zhao, C. Tian, X. Wang, Y. Jiang, L. Pei, T. Ning, J. Zheng, and J. Wang, “Photonic generation of high-accuracy triangular waveform with tunable duty cycle based on a dual-wavelength I/Q modulation,” Optical Engineering, vol. 63 no. 4, pp. 047103, 2024.
[6] X. Wang, J. Li, M. Yan, L. Pei, and T. Ning, “Periodic asymmetric function waveform generator based on polarization multiplexing modulator,” Optical Engineering, vol. 63, no. 2, pp. 025104, 2024.
[7] Y. Jiang, J. Li, M. Yan, C. Tian, L. Pei, and T. Ning, “Channelized multi-frequency measurement system based on asymmetric double sideband detection,” Applied Optics, vol. 63, 04/18, 2024.
[8] 燕苗霞, 李晶, 裴丽, 宁提纲, 郑晶晶, 王建帅, and 王创业, “基于保偏光纤双折射特性的函数波形发生器,” 光学学报, vol. 43, no. 1, pp. 0106001, 2023.
[9] 蒋玉政, 李晶, 朱伟, 裴丽, and 宁提纲, “基于锯齿波调制非平坦光频梳的信道化多频测量,” 光学学报, vol. 43, no. 22, pp. 2206001, 2023.
[10] W. Zhu, J. Li, M. Yan, L. Pei, T. Ning, J. Zheng, and J. Wang, “Photonic Multiple Microwave Frequency Measurement System with Single-Branch Detection Based on Polarization Interference,” Electronics, vol. 12, no. 2, pp. 455, 2023.
[11] M. Yan, J. Li, X. Wang, L. Pei, T. Ning, J. Zheng, and J. Wang, “Photonic generation of triangular waveform with tunable symmetry based on channelized frequency synthesis,” Applied Optics, vol. 62, 08/14, 2023.
[12] W. Zhu, J. Li, M. Yan, L. Pei, T. Ning, J. Zheng, and J. Wang, “Multiple microwave frequency measurement system based on a sawtooth-wave-modulated non-flat optical frequency comb,” Appl Opt, vol. 61, no. 35, pp. 10499-10506, Dec 10, 2022.
[13] W. Zhu, J. Li, L. Pei, T. Ning, J. Zheng, and J. Wang, “Instantaneous microwave frequency measurement with single branch detection based on the birefringence effect,” Applied Optics, vol. 61, 07/05, 2022.
[14] W. Zhu, J. Li, L. Pei, T. Ning, J. Zheng, and J. Wang, “A scalable instantaneous frequency measurement system based on single branch AC/DC detection,” Optik, vol. 268, pp. 169815, 2022/10/01/, 2022.
[15] 朱伟, 李晶, 裴丽, 宁提纲, 郑晶晶, and 王建帅, “基于偏振延时干涉的瞬时频率测量系统的分析与优化,” 光学学报, vol. 41, no. 21, pp. 2107001, 2021.
[16] J. Li, C. Wang, L. Pei, T. Ning, J. Zheng, R. He, and Y. Li, “Generation of an optical triangular-shaped pulse train with variable symmetry by using an I/Q modulator,” Optics Letters, vol. 45, no. 6, pp. 1411-1414, Mar, 2020.
[17] J. Li, L. Pei, T. Ning, J. Zheng, Y. Li, and R. He, “Measurement of Instantaneous Microwave Frequency by Optical Power Monitoring Based on Polarization Interference,” IEEE/OSA Journal of Lightwave Technology, vol. 38, no. 8, pp. 2285-2291, 01/30, 2020.
[18] Y. He, J. Li, Y. Bao, and S. Dong, “Performance analysis on a filter-less frequency doubling generator with tunable phase shift based on dualpolarization modulation,” Optoelectronics Letters, vol. 16, no. 3, pp. 190-194, 2020/05/01, 2020.
[19] J. Li, T. Ning, L. Pei, and J. Zheng, “Photonic generation of triangular-shaped waveform signal with adjustable symmetrical coefficient,” Journal of Modern Optics, vol. 66, pp. 1-9, 06/28, 2019.
[20] J. Li, Z. Hao, L. Pei, T. Ning, and J. Zheng, “Frequency-doubled triangular shape lightwave generation with a flexible modulation index,” Chinese Optics Letters, vol. 15, no. 9, pp. 090603, 2017/09/10, 2017.
[21] Z. Hao, J. Li, C. Wang, and J. Yuan, “Performance study of optical triangular-shaped pulse generation with full duty cycle,” Chinese Optics Letters, vol. 15, pp. 110601, January 01, 2017, 2017.
[22] J. Li, J. Sun, W. Xu, T. Ning, L. Pei, J. Yuan, and Y. Li, “Frequency-doubled triangular-shaped waveform generation based on spectrum manipulation,” Optics letters, vol. 41, pp. 199-202, 01/14, 2016.
[23] J. Li, T. Ning, L. Pei, W. Jian, J. Zheng, H. You, and X. Wen, “Study on a radio over fibre link with improved receiver sensitivity based on polarization modulation,” Infrared and Laser Engineering, vol. 45, no. 6, pp. 0617004, 2016.
[24] 李晶, 宁提纲, 裴丽, 简伟, 油海东, 陈宏尧, and 张婵, “基于二次外差法的八倍频毫米波光子发生器特性,” 红外与毫米波学报, vol. 34, no. 3, pp. 352-359, 2015.
[25] J. Li, T. Ning, L. Pei, J. Zheng, J. Sun, Y. Li, and j. Yuan, “Quasi-optical single-sideband modulation with continuous carrier-to-sideband ratio tunability,” Chinese Optics Letters, vol. 13, no. 8, pp. 080606, 2015.
[26] 李晶, 宁提纲, 裴丽, 简伟, 郑晶晶, 油海东, 孙剑, 王一群, and 李超, “基于谐波拟合产生周期性三角形光脉冲串的实验研究,” 物理学报, vol. 63, no. 15, pp. 154215, 2014.
[27] J. Li, T. Ning, L. Pei, J. Zheng, Y. Li, J. Yuan, Y. Wang, C. Zhang, and H. Chen, “Simulation study on an improved frequency-doubled triangular- shaped pulse train generator with reduced harmonic distortion,” Chinese Optics Letters, vol. 12, pp. 120602-120607, January 01, 2014, 2014.
[28] J. Li, T. Ning, L. Pei, W. Jian, J. Zheng, H. You, H. Chen, and C. Zhang, “Performance analysis on an instantaneous microwave frequency measurement with tunable range and resolution based on a single laser source,” Optics & Laser Technology, vol. 63, pp. 54-61, 2014/11/01/, 2014.
[29] J. Li, T. Ning, L. Pei, W. Jian, H. You, X. Wen, H. Chen, C. Zhang, and J. Zheng, “Theory study on a photonic-assisted radio frequency phase shifter with direct current voltage control,” Chinese Physics B, vol. 23, pp. 104216, 08/10, 2014.
[30] 李晶, 宁提纲, 裴丽, 简伟, 油海东, 陈宏尧, 张婵, and 李超, “ 基于双平行马赫曾德调制器的动态可调光载波边带比光单边带调制:理论分析与实验研究,” 物理学报, vol. 62, no. 22, pp. 224210, 2013-06-29, 2013.
[31] J. Li, T. Ning, L. Pei, W. Jian, H. You, H. Chen, and C. Zhang, “Photonic-Assisted Periodic Triangular-Shaped Pulses Generation With Tunable Repetition Rate,” IEEE Photonics Technology Letters, vol. 25, pp. 952-954, 05/01, 2013.
[32] J. Li, T. Ning, L. Pei, W. Jian, H. You, H. Chen, C. Li, C. Zhang, and S. Ma, “Simulation analysis of an improved optical triangular-shaped pulse train generator based on quadrupling RF modulation incorporating fiber dispersion-induced power fading,” Optical Fiber Technology, vol. 19, no. 6, Part A, pp. 574-578, 2013/12/01/, 2013.
[33] J. Li, T. Ning, L. Pei, S. Gao, H. You, H. Chen, and N. Jia, “Performance analysis of an optical single sideband modulation approach with tunable optical carrier-to-sideband ratio,” Optics & Laser Technology, vol. 48, pp. 210-215, 2013/06/01/, 2013.
[34] J. Li, X. Zhang, B. Hraimel, T. Ning, L. Pei, and K. Wu, “Performance Analysis of a Photonic-Assisted Periodic Triangular-Shaped Pulses Generator,” IEEE/OSA Journal of Lightwave Technology, vol. 30, no. 11, pp. 1617-1624, 2012.
[35] J. Li, T. Ning, L. Pei, W. Peng, N. Jia, Q. Zhou, and X. Wen, “Photonic generation of triangular waveform signals by using a dual-parallel Mach–Zehnder modulator,” Optics Letters, vol. 36, no. 19, pp. 3828-3830, 2011/10/01, 2011.
[36] J. Li, T. Ning, P. Li, C. Qi, S. Gao, Q. Zhou, and N. Jia, “Simulation analysis of a photonic ultrawideband pulse generator by using a dual-parallel Mach-Zehnder modulator,” Optical Engineering, vol. 50, no. 10, pp. 105007, 2011.
[37] J. Li, T. Ning, L. Pei, C. Qi, Q. Zhou, X. Hu, and S. Gao, “60 GHz millimeter-wave generator based on a frequency-quadrupling feed-forward modulation technique,” Optics Letters, vol. 35, no. 21, pp. 3619-3621, 2010/11/01, 2010.
[38] J. Li, T. Ning, L. Pei, C. Qi, X. Hu, and Q. Zhou, “An Improved Radio Over Fiber System With High Sensitivity and Reduced Power Degradation by Employing a Triangular CFBG,” IEEE Photonics Technology Letters, vol. 22, no. 7, pp. 516-518, 2010.
[39] J. Li, T. Ning, L. Pei, C. Qi, X. Hu, and Q. Zhou, “Photonic frequency-quadrupling scheme for millimeter-wave generation by employing feed-forward modulation technique,” Optics Express, vol. 18, no. 3, pp. 2503-2508, 2010/02/01, 2010.
[40] J. Li, T. Ning, L. Pei, and C. Qi, “Optical ultra-wideband pulse generation and distribution using a dual-electrode Mach-Zehnder modulator,” Chinese Optics Letters, vol. 8, pp. 138-141, 02/01, 2010.
[41] J. Li, T. Ning, L. Pei, and C. Qi, “A bidirectional 60GHz RoF system based on FWM in a semiconductor optical amplifier,” Optics Communications, vol. 283, no. 10, pp. 2238-2242, 2010/05/15/, 2010.
[42] J. Li, T. Ning, L. Pei, and C. Qi, “Scheme for a High-Capacity 60 GHz Radio-Over-Fiber Transmission System,” Journal of Optical Communications and Networking, vol. 1, no. 4, pp. 324-330, 2009/09/01, 2009.
[43] J. Li, T. Ning, L. Pei, and C. Qi, “Millimeter-wave radio-over-fiber system based on two-step heterodyne technique,” Optics Letters, vol. 34, no. 20, pp. 3136-3138, 2009/10/15, 2009.
1. 李晶,宁提纲,等. 基于双电极调制器产生毫米波超宽带脉冲的装置.[P]. 中国,2008, ZL2008 1 0240116.7
2. 李晶,宁提纲,等. 基于三角形谱光纤光栅直接调制直接检波生成毫米波装置.[P]. 中国,2009,ZL2009 1 0241944.7
1. 北京交通大学优秀博士学位论文
2. 北京交通大学电信学院科研论文二等奖
3. 中国通信学会科学技术奖二等奖, 2024年
