王飞，重庆北碚人，工学博士，教授，研究生导师。2005年获西南大学光学专业理学硕士学位，2010年获华中科技大学电子科学与技术专业工学博士学位。2005年至2019年就职于重庆理工大学，先后任讲师/副教授/教授，英国布里斯托大学访问学者，2019年至今就职于西南大学担任教授，承担《电磁学》、《大学物理》、《非线性光学》等本科、研究生课程的教学任务。

在Chaos Solitons & Fractals，Journal of Lightwave Technology，Optics and Laser Technology，Optics Express，IEEE Photonics Technology Letters等国际主流学术期刊、学术会议上发表学术论文150余篇；授权国家发明专利、国际发明专利6件；2010年获第9届华中科技大学研究生“科技十佳”称号；2014年获重庆市第八届青年科技奖人才项目；2016年获重庆市科学技术奖自然科学奖三等奖。

研究领域

激光雷达，光电子器件，微波光子学，光纤激光器，半导体激光器非线性动力学等。

科研项目

作为项目负责人承担国家自然基金、教育部科学技术研究重点项目、重庆市自然基金重点项目等科研项目20余项。

1. 光载毫米波太赫兹发射器基础研究, 中央高校基本科研业务费（引进人才计划项目）, 主持

2. 基于增强多模相互作用的混沌激光二极管的WDM-PON保密通信基础应用探究，重庆市自然基金面上项目，主持

3. 激光雷达与智能光节点研究，国家高端外国专家项目（外专千人计划），中组部，主研

4. 下一代融合的无线和有线宽带接入网基础研究，国家高端外国专家项目，主持

5. 光子集成亚太赫兹无线通信源的非线性动力学研究及器件设计，国家自然科学基金面上项目，主持

6. 基于量子阱FP-SOA的多波长全光时钟恢复及光子集成器件基础研究，国家自然科学基金青年基金，主持

7. 多用户光载超宽带无线通信系统关键组件及其光子集成基础研究，教育部科学技术研究重点项目，主持

8. 新一代无线和有线信号融合波分复用无源光网络双向通信系统基础研究，重庆市自然基金重点项目，主持

9. 先进光电信息器件及其应用，重庆理工大学科研创新团队，主持

10. 40-160Gb/s新型多波长全光时钟恢复器基础研究，重庆市自然科学基金，主持

11. 光载超宽带无线通信系统中射频脉冲信号产生与调制，重庆市教育委员会科学技术研究项目，主持

12. 适合下一代光网络的全光时钟恢复技术研究，重庆工学院博士科研启动基金项目，主持

13. 半导体光放大器的双折射特性及其在光通信中的应用研究，重庆市自然科学基金，主持

14. 下一代网络中的高速全光数据格式转换，重庆市教育委员会科学技术研究项目，主持

15. 光控微波波束形成器中的延时控制和传输噪声特性研究，国家重大基础研究计划（973计划），主研

16. 40-80Gb/s新型全光波长转换器的研究，国家高技术研究发展计划（863计划），主研

代表论文：

在Chaos Solitons & Fractals，Journal of Lightwave Technology，Optics and Laser Technology，Optics Express等国际主流学术期刊、学术会议上发表学术论文150余篇。

1. Jiacheng Li (李佳澄), F. Wang*, Chongyu Huang, Ultrafast real-time parallel random bit generation based on a directly modulated chaotic semiconductor laser, Chaos, Solitons and Fractals 198 (2025) 116568

2. Jingyang Wang (王敬阳), F. Wang*, Tao Deng, Zhengmao Wu, Multi-wavelength fiber laser incorporating enhanced four-wave mixing and Brillouin random lasing resonance, Infrared Physics & Technology, Volume 151, December 2025, 106136

3. Longxuan Ma (马龙轩), F. Wang*, Tao Deng, Zhengmao Wu, Spatially confined liquid temperature and alcohol concentration sensing based on forward Brillouin scattering in highly nonlinear fiber, Optics & Laser Technology, Volume 192, Part B, December 2025, 113587

4. J. Zhang (张进进) and F. Wang*, Multi-wavelength Brillouin-erbium random fiber laser incorporating enhanced FWM effects, Optics & Laser Technology 183 (2025) 112373.

5. Yonggang Wu (吴永刚), F. Wang*, Tao Deng, Jinjin Zhang, Guangqiong Xia, Zhengmao Wu, Long-range temperature sensing based on forward Brillouin scattering in highly nonlinear fiber, Optics & Laser Technology, Volume 181, Part A, February 2025, 111619.

6. Deng-wang Hu (胡灯望), F. Wang*, Jia-cheng Li, Tao Deng, Jia-gui Wu, Guang-qiong Xia, Zheng-mao Wu, Wideband chaotic comb source using a weak-resonant-cavity Fabry-Perot laser diode subject to optical feedback for parallel random number generation, Chaos, Solitons and Fractals 188 (2024) 115458.

7. Jinjin Zhang (张进进), F. Wang*, Xulan Hua, Ziye Gao, Tao Deng, Guangqiong Xia, Zhengmao Wu, Broadband optical frequency comb generation based on a dual-pumped Brillouin-erbium fiber laser, Journal of Lightwave Technology,VOL. 42, NO. 8, 2945-2950, APRIL 15, 2024

8. Xulan Hua (华绪兰), F. Wang*, Jinjin Zhang, Guangqiong Xia, Zhengmao Wu, Single-longitudinal-mode narrow linewidth broadband tunable Brillouin random laser including dispersion compensation fibers, Optics & Laser Technology 170 (2024) 110249

9. Zhengshan Yin (音正山), F. Wang*, Tao Deng, Dengwang Hu, Guangqiong Xia and Zhengmao Wu, Multi-channel chaotic signal generation using a weak resonant cavity Fabry–Perot laser diode subject to self-phase-modulated feedback, Laser Phys. Lett. 20 (2023) 115802 (6pp).

10. L. Tao (陶柳媛), F. Wang*, Z. Wu and G. Xia, “Stable and tunable PT-symmetric single-longitudinal-mode fiber laser using a nonreciprocal Sagnac loop,” IEEE Access, 2023, 11: 23127-23135. IDS: A1CR2

11. L. Tao (陶柳媛), F. Wang*, G. Xia and Z. Wu, “Tunable single-longitudinal-mode narrow linewidth Brillouin fiber laser based on PT symmetry,” Laser Phys. Lett., 2023, 20(5): 055103. IDS: E5MI2

12. F. Wang*, Guangqiong Xia , Tao Deng , Jiagui Wu , Liuyuan Tao, Liang Peng, and Zhengmao Wu, “Tunable Chaotic External-Cavity Semiconductor Laser With Time-Delay Signature Suppression Including a Broadband Chirped FBG,” J. Lightwave Technol., VOL. 40, NO. 15, pp: 5260-5266, AUGUST 1, 2022.

13. F. Wang*, Zhengmao Wu, Guangqiong Xia, “Switchable wide-band multi-wavelength fiber laser via Brillouin random lasing resonance,” Optics & Laser Technology 156 (2022) 108606 1-8

14. Fei Wang, W. Kang (康雯), “Investigation of optical short pulse generation using intensity modulation for LiDAR and free-space communications,” Optica Applicata, Vol. LI, No. 1, 97-107, 2021.

15. F. Wang, W. Kang (康雯), “Wideband optical frequency comb generation using a fiber re-circulating loop cascaded with a spectrum expander including highly nonlinear fiber,” Optica Applicata, Vol. LI, No. 2, 181-191, 2021.

16. F. Wang, R. Y. Yuan (袁润月), Investigation of a tunable and switchable multi-wavelength bidirectional Brillouin-erbium fiber ring laser, Optica Applicata, Vol. LI, No. 3, 375-388, 2021.

17. F. Wang* and Y. Gong (宫一凡), "Tunable and Switchable Multi-Wavelength Erbium-Brillouin Random Fiber Laser Incorporating a Highly Nonlinear Fiber," Journal of Lightwave Technology, vol. 38, no. 15, pp. 4093-4099, 2020, doi: 10.1109/JLT.2020.2984561.

18. F. Wang* and Y. Gong (宫一凡), " Switchable Wide-Band Multi-Wavelength Brillouin-Erbium Fiber Laser Based on Random Distributed Feedback," IEEE Access, date of publication December 3, 2020, VOLUME 8, 2020 218614- 218620.

19. Fei Wang, Mengmeng Peng (彭蒙蒙), Investigation of a selectable multi-passband microwave photonic filter based on cascaded optical comb filters, Optica Applicata , Vol. LI, No. 3, 457-467, 2021.

20. Mengmeng Peng (彭蒙蒙), Fei Wang*, Lun Shi, Jingxin Huang, Wen Kang, “Reconfigurable and tunable multi-tap bandpass microwave photonic filter based on a hybrid-gain-assisted multi-wavelength fiber ring laser,” Optica Applicata, Vol. XLIX, No. 3: 499-507, 2019

21. Lun Shi (史伦), F. Wang*, Mengmeng Peng, Wen Kang and Jingxin Huang,A Novel Scheme for Frequency-Space Switchable Optical Frequency Comb Generation, Asia Communications and Photonics Conference (ACP)，OSA 2018.

22. Jun Gu (顾军), F. Wang*, Youxi Lu, Mengmeng Peng, Lun Shi, Wen Kang, Jingxin Huang, Polarization dependence of stimulated Brillouin scattering-based switchable microwave photonic filter, Optica Applicata, Vol. XLIX, No. 1: 5-11, 2019.

23. Jun Gu (顾军), F. Wang*, Youxi Lu, Mengmeng Peng, Lun Shi, and Chang-hee Lee，Cascaded fiber Sagnac loop-based microwave photonic multiband bandpass filter with a selectable passband frequency，Chinese Optics Letters，15(11), 110603，1-5(2017).

24. Youxi Lu （路侑锡）, Fei Wang *, Jun Gu, Lun Shi, Mengmeng Peng, Jingxin Huang, Wen Kang, Chang-hee Lee, Photonic generation of broadly tunable radio frequency signal using a reflective semiconductor optical amplifier, Optica Applicata, Vol. XLIX, No. 1: 27-36, 2019

25. Xin Zhang (张鑫), F. Wang*, Jiagui Wu, Qiong Yu, Jun Gu, Youxi Lu, A reconfigurable microwave photonic filter, Asia Communications and Photonics Conferene (ACP2016), AS3G.3

26. F. Wang*, Qiong Yu (余琼), Jun Gu, Youxi Lu, Phase-coded microwave signals generation using a dual parallel construction including two phase modulators, Optics & Laser Technology, 2018,105:135-138

27. Qiong Yu (余琼), F. Wang*, Weibin Wang, Xin Zhang, Youxi Lu, Jun Gu, and Huihui Xiao, “Photonic Generation of Phase-coded Microwave Signals Based on Dual Parallel Phase Modulators”, PIERS2016, 8–11 August, 1596-1599.

28. Weibin Wang (王维彬), F. Wang, Qiong Yu, Xin Zhang, Youxi Lu, and Jun Gu, “Delivering dispersion-managed soliton and Q-switched pulse in fiber laser based on graphene and nonlinear optical loop mirror”, Optics & Laser Technology, 2016, 85:41-47.

29. Weibin Wang (王维彬), F. Wang, Yu Zhang, Huan Ma, Qiong Yu, and Xin Zhang, “Passively mode-locked figure-eight fiber laser using a compact power-imbalanced nonlinear optical loop mirror”, JRLR, Journal of Russian Laser Research, May 2016, Volume 37, Issue 3, pp 265–272

30. F. Wang*, Huan Ma (马欢), Converged 10 Gbit/s 4-PAM signal and 1 Gbit/s MB-UWB signal transport over single wavelength,Optik, 147 (2017) 414–419.

31. Huan Ma (马欢), F. Wang*, Weibin Wang, Xin Zhang, Qiong Yu, “Converged UWB and multi-level wired signal downstream transport over single wavelength in WDM-PON”, Optica Applicata, Vol. XLV, No. 4, 2015.

32. Long-Sheng Tan (谭龙盛), F. Wang*, Huan Ma, Qiang Hu, Xiao-Fang Zhao,All-optical binary phase-coded UWB signal generation using DWDM-based multi-channel frequency discriminator, Optics Communications, 312 (2014) 153–158.

33. F. Wang, Enming Xu,All-optical UWB doublet pulses generation by using a delay interferometer, Optics Communications, 297 (2013) 38–42.

34. F. Wang, Y. Yu, Y. Zhang and X. L. Zhang, “All-Optical Clock Recovery Using a Single Fabry-Perot Semiconductor Optical Amplifier”, J. Lightwave Technol., vol. 30, no. 11, pp. 1632-1637, 2012.

35. Y. Yu, J. J. Dong, E. M. Xu, X. Li, L. N. Zhou, F. Wang and X. L. Zhang, "Single Passband Microwave Photonic Filter with Continuous Wideband Tunability Based on Electro-Optic Phase Modulator and Fabry–Pérot Semiconductor Optical Amplifier," J. Lightwave Technol., 29(23), 3542-3550 (2011).

36. F. Wang,Tunable 12×10 GHz mode-locked semiconductor fiber laser incorporating a Mach-Zehnder interferometer filter, Optics & Laser Technology, Volume 43, Issue 4, pp 848-851, June 2011.

37. F. Wang, Xinliang Zhang, Enming Xu,Investigation of data-format-transparent multiwavelength all-optical clock recovery using a single FP-SOA, Optics & Laser Technology 43 (2011) 1203–1207.

38. F. Wang, En-Ming Xu, Jian-Ji Dong, Xin-Liang Zhang, A tunable and switchable single-longitudinal-mode dual-wavelength fiber laser incorporating a reconfigurable dual-pass Mach–Zehnder interferometer and its application in microwave generation, Optics Communications 284 (2011) 2337–2340.

39. F. Wang, Yunhong Ding, Jianji Dong, Xinliang Zhang，All-optical switchable UWB pulses generation, modulation and transmission, Optics Communications 284 (2011) 2448–2454.

40. F. Wang, Jianji Dong, Enming Xu, and Xinliang Zhang, All-optical UWB generation and modulation using SOA-XPM effect and DWDM-based multi-channel frequency discrimination, Optics Express Vol. 18, Iss. 24, pp. 24588–24594 (2010).

41. F. Wang, X. Zhang, Y. Yu, X. Huang,82-Channel Multiwavelength Comb Generation in a SOA fiber ring laser, Optics & Laser Technology, 42(2):285–288, 2010.

42. F. Wang, Xinliang Zhang, Enming Xu, Yu Zhang, “Tunable 19 × 10 GHz L-band FP- SOA based multi- wavelength mode-locked fiber laser” Opt. Commun., 2010, 283(7): 1434-1437.

43. F. Wang, Y. Yu, X. Huang, and X. Zhang, "Single and Multiwavelength All-Optical Clock Recovery Using Fabry-Perot Semiconductor Optical Amplifier," IEEE Photon. Technol. Lett., vol. 21, no. 16, pp. 1109-1111, Aug. 2009.

44. F. Wang, Xin-Liang Zhang, Jian-Ji Dong, Xi Huang, “A Fiber Ring Laser Incorporating Dual Mode-locking Mechanism”, Optics & Laser Technology, 2009, 41(1): 85-88.

45. F. Wang, Yu Yu, Xi Huang, Xinliang Zhang, “All-optical clock recovery of 20 Gbit/s NRZ-DPSK signals using polarization-maintaining fiber loop mirror filter and semiconductor optical amplifier fiber ring laser”, Opt. Commun., 282 (2009) 2292–2296.

46. Yu Yu, Xinliang Zhang, F. Wang, Dexiu Huang, “Simple and flexible generation of vestigial side band modified duobinary return-to-zero signals at 10, 20 and 40 Gb/s”, Opt. Commun., 2010, 283(10): 2074-2078.

47. Jianji Dong, Xinliang Zhang, F. Wang, Wei Hong, Dexiu Huang, “Experimental study of SOA-based NRZ-to-PRZ conversion and distortion elimination of amplified NRZ signal using spectral filtering”, Optics Communications, 2008, 281: 5618–5624.

48. F. Wang, Xin-Liang Zhang, Jian-Ji Dong, “A novel actively and passively mode-locking semiconductor optical amplifier fiber ring laser”, Opt. Commun., 281 (2008) 2868–2873.

49. F. Wang, Xin-Liang Zhang, Jian-Ji Dong, Yu Yu, Zheng Zhang, Eleven-wavelength switchable fiber ring laser with a dispersion compensation fiber and a delayed interferometer, Optics Communications, 2008, 281: 5842-5845.

50. Xin-Hong Jia, Dong-Zhou Zhong, F. Wang, Hai-Tao Chen, “Detailed modulation response analyses on enhanced single-mode QWS-DFB lasers with distributed coupling coefficient”, Opt. Commun., 2007,277:166-173.

51. Xin-Hong Jia, Dong-Zhou Zhong, F. Wang, Hai-Tao Chen, “Dynamic single-mode and modulation characteristics analyses for λ/4 phase-shifted distributed feedback lasers with chirped grating”, Opt. Commun., 2007, 279 (2): 356-363.

52. F. Wang, Guang-Qiong Xia, Zheng-Mao Wu, “All-optical Frequency Multiplication /recovery Based on the Semiconductor Optical Amplifier Ring Cavity”, Opt. Commun., 2006, 257: 334-339.

发明专利：

1. 徐恩明，潘时龙，王飞，李培丽，宽带调谐高Q值单通带微波光子滤波器，2012.12，中国，201210519675.8

2. 邓涛, 钟海斌, 王昱, 曹俊, 唐曦, 林晓东, 王飞, 谢瑛珂, 一种基于储备池混沌预测和交织编码的保密通信方法及系统, 专利号：ZL 202411735410.0, 授权公告号：CN 119602932B, 专利申请日：2024年11月29日, 授权公告日：2025年09月19日

3.邓涛, 吴雪, 王飞, 谢瑛珂, 林晓东, 唐曦, 王彦超, 马林, 一种基于频率编码DFB神经元的可重构逻辑运算装置及方法, 申请/专利号：CN202311751996.5, 申请日期：2023-12-19,公开/公告号：CN117688997A, 公开/公告日：2024-03-12

4. 邓涛, 邓天杰, 林晓东, 谢瑛珂, 王飞, 钟海斌, 一种基于VCSEL的时延特征隐藏的混沌保密通信装置, 申请/专利号：CN202410509071.8, 申请日期：2024-04-25, 公开/公告号：CN118214491A, 公开/公告日：2024-06-18

5. 李旭光, 赵宛杉, 曹圆婧, 王馨悦, 许龙, 孙凯, 贾伟尧, 邓涛, 李加兴, 谢瑛珂, 王飞, 杨铁, 谭兴文, 桑文龙, 张巧明, 王彪, 螺旋型溶液浓度光纤传感仪及溶液浓度检测装置申请/专利号：CN202411361541.7申请日期：2024-09-27公开/公告号：CN119125046A公开/公告日：2024-12-13

6. 熊陶, 高子叶, 边嘉仪, 邓涛, 谢瑛珂, 唐曦, 林晓东, 王飞, 吴加贵, Covert communication system based on femtosecond laser, 国际发明专利,专利授权,授权公告号RP:F/PT/C/2024/13359授权公告日2024-07-24

荣誉奖励：

1. 2016年，重庆市科学技术奖自然科学奖三等奖（排名第一）

2. 2014年，重庆市第八届青年科技奖人才项目

3. 2010年，华中科技大学研究生“科技十佳”

联系方式

E-mail：wangf17@swu.edu.cn