个人简介
基本情况姓名：
王目光

职务：


职称：
教授

学历：
研究生

学位：
博士

通信地址：


邮编：


办公电话：


电子邮箱：
mgwang@bjtu.edu.cn


教育背景 王目光，男，博士，教授，博士生导师。1999年毕业于山东大学光电子信息工程系专业，获工学学士学位；2004年毕业于北京交通大学通信与信息系统专业，获工学博士学位。2004年至今在北京交通大学光波技术研究所工作。2008年入选北京市科技新星计划，2009年入选教育部新世纪优秀人才支持计划，2012年国家公派以访问身份留学加拿大渥太华大学一年。


工作经历


研究方向 电磁场与微波技术
电子与通信工程（专业学位）
全光交换、特种光纤及器件
全光交换、特种光纤、光电器件及基于智能光纤传感的物联网



招生专业 电子科学与技术硕士
电子与通信工程硕士
信息与通信工程硕士
信息与通信工程博士



科研项目 主要研究方向包括高速光纤通信系统关键技术和器件、新型光纤传感、全光信号处理、微波光子和光纤通信与无线通信融合技术，欢迎好学、勤奋、踏实、乐观、主动性强的学生报考。
主持和参加的科研项目主要有：


1. 国家自然科学基金项目“基于光电振荡的高精度快响应多参量光纤传感技术研究”
2. 中央高校专项资金重点项目“基于微波光子的海洋环境监测技术”
3. 国家自然科学基金项目“光电振荡器关键技术及应用研究”
4. 中央高校专项资金项目“微波光子雷达技术”
5. 中央高校专项资金项目“基于OEO和CRoF技术的5G前传网络设计”
6. 北京市教委：北京高等学校“青年英才计划”
7. 教育部新世纪优秀人才支持计划
8. 国家自然科学基金：超高采样偏振不敏感宽带全光模数转换技术的研究
9. 北京市科委:北京市科技新星计划
10. 中央高校专项资金项目“端到端有连接、有信令系统的光路交换网络研究”
11. 科技部973计划课题：面向光路交换网络的光纤器件理论与关键技术研究
12. 科技部“863”:160Gbit/s-泵多纤光传输技术的研究
13. 国家自然科学基金“超宽带双芯光子晶体光纤及相关器件研究”
14. 国家自然科学基金“基于时间透镜的光学傅立叶变换在实时测量中的应用”
15. 中央高校专项资金项目“基于双波长激光器的微波光子混频器的研究”




教学工作 已主讲本科生课程：《全光通信网》、《光通信技术基础》、《光纤通信概论》、《光纤通信研究性专题》；研究生课程：《光通信网络》。


论文/期刊 Selected Publications

[54]. Y Tang, M.Wang^*, B Wu, Y Dong, H Xiao, J Zhang, H Mu, G Fan,High-sensitivity displacement sensing based on an OEO incorporating anunbalanced MZI, Optics & Laser Technology 121, 105816, 2020.
[53]. M Han, M. Wang^*, N Zhang, H Mu, B Wu, Y Liu, F Yan, Abandwidth-enhanced polarization division multiplexed intensitymodulation-direct detection system utilizing a dual polarization-DPMZM, OpticalFiber Technology 53, 102042, 2019
[52]. Jing Zhang, Muguang Wang*, Yu Tang, Qi Ding, andNaihan Zhang, "Scale factor improvement for angular velocity measurementbased on an optoelectronic oscillator," Opt. Lett. 44, 5194-5197 (2019)
[51]. Y. Guo, M. Wang*, Y. Li, H. Mu, B. Wu, Y. Liu,F. Yan. "Joint Modulation Format Identification and Frequency OffsetEstimation Based on Superimposed LFM Signal and FrFT." Ieee PhotonicsJournal 11(5): 1-12, 2019
[50]. Ding,Q., Wang, M.^*, Wu, B., Zhang, J., Mu, H., Liu, Y., & Yan,F. (2019). Tunable optoelectronic oscillator based on a polarization-dependentphase modulator cascaded with a linear chirped FBG.Optics & LaserTechnology,119, 105643, 2019.
[49]. Mu, H., Wang,M., & Li, M. (2019). Power-efficient FCC-compliant UWB generator usingpolarization-maintaining FBG-based spectral shaper and incoherentwavelength-to-time mapping.Optical Fiber Technology,50, 271-276,2019.
[48]. Liu, J.,Lu, P., Mihailov, S. J., Wang, M., & Yao, J. (2019). Real-timerandom grating sensor array for quasi-distributed sensing based onwavelength-to-time mapping and time-division multiplexing. Optics letters,44(2), 379-382, 2019.
[47]. Sun, J., Wang, M.*, Tang, Y., Wu, B., Zhang, J., Li, T., & Shi, Y. (2019). Width-tunableoptical pulse generator based on the polarization-sensitive feature of LiNbO 3crystal in Mach–Zehnder modulator.Optical Engineering,58(6),063104, 2019.
[46]. Sun, C., Wang, M.*, Dong, Y., Ye, S., & Jian, S. (2019). Simultaneousmeasurement of magnetic field and temperature based on NCF cascaded with ECSFin fiber loop mirror.Optical Fiber Technology,48, 45-49, 2019.
[45]. Jian,S., Tang-Jun, L., Mu-Guang, W.*, Nan, J., Yan-Chao, S., Chun-Can, W.,& Su-Chun, F. (2019). Evolution of non-frequency shift components of pulsetail in normal dispersion region of highly nonlinear fiber.ACTA PHYSICASINICA,68(11), 2019.
[44]. Yin, B.,Wu, S., Wang, M., Liu, W., Li, H., Wu, B., & Wang, Q. (2019).High-sensitivity refractive index and temperature sensor based on cascadeddual-wavelength fiber laser and SNHNS interferometer.Opticsexpress,27(1), 252-264, 2019.
[43]. Tang,Y., Wang, M.^*, Wu, B., Zhang, J., Ding, Q., Mu, H., ... &Yan, F. (2018). Chromatic dispersion measurement based on a high-Qoptoelectronic oscillator incorporating cascaded FIR and IIR filters.OSAContinuum,1(4), 1205-1214, 2018
[42]. J.Zhang, M. Wang^*, Y. Tang, Q. Ding, B. Wu, Y. Yang, et al.,"High-sensitivity measurement of angular velocity based on anoptoelectronic oscillator with an intra-loop Sagnac interferometer,"Optics letters, vol. 43, pp. 2799-2802, 2018.
[41]. Y. Yang, M. Wang^*, Y. Shen, Y. Tang, J. Zhang, Y. Wu, et al.,"Refractive Index and Temperature Sensing Based on an OptoelectronicOscillator Incorporating a Fabry–Perot Fiber Bragg Grating," IEEEPhotonics Journal, vol. 10, pp. 1-9, 2018.
[40]. C. Sun,Y. Dong, M. Wang^*, and S. Jian, "Liquid level andtemperature sensing by using dual-wavelength fiber laser based on multimodeinterferometer and FBG in parallel," Optical Fiber Technology, vol. 41,pp. 212-216, 2018.
[39]. H. Mu, M.Wang, B. Wu, Y. Tang, J. Zhang, and Q. Ding, "Background-freemicrowave pulse generator based on both bright and dark temporal gate and asingle photodetector," Optics Communications, vol. 425, pp. 146-151, 2018.
[38]. H. Mu, M.Wang, Y. Tang, J. Zhang, and S. Jian, "Photonic generation ofFCC-compliant UWB pulses based on modified Gaussian quadruplet and incoherentwavelength-to-time conversion," Optics Communications, vol. 411, pp.170-174, 2018.
[37]. Y. Dong,B. Wu, M. Wang, H. Xiao, S. Xiao, C. Sun, et al., "Magnetic fieldand temperature sensor based on D-shaped fiber modal interferometer andmagnetic fluid," Optics & Laser Technology, vol. 107, pp. 169-173,2018.
[36]. B. Yin, M.Wang, S. Wu, Y. Tang, S. Feng, and H. Zhang, "High sensitivity axialstrain and temperature sensor based on dual-frequency optoelectronic oscillatorusing PMFBG Fabry-Perot filter," Optics Express, vol. 25, pp. 14106-14113,2017.
[35]. B. Yin, M.Wang, S. Wu, Y. Tang, S. Feng, Y. Wu, et al., "Fiber ring laser basedon MMF-PMFBG-MMF filter for three parameters sensing," Optics express,vol. 25, pp. 30946-30955, 2017.
[34]. B. Wu, M.Wang^*, Y. Tang, J. Sun, J. Zhang, F. Yan, et al., "Opticalsingle sideband modulation with tunable optical carrier-to-sideband ratio usinga modulator in a Sagnac loop," Optics & Laser Technology, vol. 91, pp.98-102, 2017.
[33]. Y. Tang, M. Wang^*, J. Sun, B. Wu, J. Zhang, Q. Ding, et al.,"Optical signal processing based on an optoelectronic oscillator employinga polarization-dependent phase modulator," in Microwave Photonics (MWP),2017 International Topical Meeting on, 2017, pp. 1-4.
[32]. Y. Tang, M. Wang^*, J. Sun, B. Wu, J. Zhang, Q. Ding, et al.,"Multifold clock recovery and demultiplexing based on apolarization-dependent phase modulator incorporated frequency-doublingoptoelectronic oscillator," Optics Communications, vol. 403, pp. 304-311,2017.
[31]. J. Sun,N. Jia, T. Li, and M. Wang, "Simultaneous wavelength exchange and2R regeneration for two optical time division multiplexing signals by a singlehighly nonlinear fiber," Optical Engineering, vol. 56, p. 116106, 2017.
[30]. C. Sun, M.Wang^*, and S. Jian, "Experimental and theoretical study ofthe in-fiber twist sensor based on quasi-fan Solc structure filter,"Optics express, vol. 25, pp. 19955-19965, 2017.
[29]. J. Liu, M.Wang^*, Y. Tang, Y. Yang, Y. Wu, W. Jin, et al., "SwitchableOptoelectronic Oscillator Using an FM-PS-FBG for Strain and TemperatureSensing," IEEE Photonics Technology Letters, vol. 29, pp. 2008-2011, 2017.
[28]. J. Liu, M.Wang^*, X. Liang, Y. Dong, H. Xiao, and S. Jian,"Erbium-doped fiber ring laser based on few-mode-singlemode-few-mode fiberstructure for refractive index measurement," Optics & LaserTechnology, vol. 93, pp. 74-78, 2017.
[27]. B. Wu, M.Wang^*, Y. Tang, J. Sun, and S. Jian, "Photonic MicrowaveSignal Mixing Using Sagnac-Loop-Based Modulator and Polarization-DependentModulation," IEEE Photonics Journal, vol. 8, pp. 1-8, 2016.
[26]. B. Wu, M.Wang^*, J. Sun, B. Yin, H. Chen, T. Li, et al.,"Frequency-and phase-tunable optoelectronic oscillator based on a DPMZMand SBS effect," Optics Communications, vol. 363, pp. 123-127, 2016.
[25]. C. Sun, M.Wang^*, J. Liu, S. Ye, L. Liang, and S. Jian, "Fiber ringcavity laser based on modal interference for curvature sensing," IEEEPhotonics Technol. Lett, vol. 28, pp. 923-926, 2016.
[24]. H. Mu, M.Wang, J. Ye, and S. Jian, "Photonic generation of bipolardirect-sequence UWB signals based on optical spectral shaping and incoherentfrequency-to-time conversion," Optics Communications, vol. 369, pp.120-125, 2016.
[23]. B. Wu,M. Zhu, M. Xu, J. Wang, M. Wang, F. Yan, et al., "Flexiblecompensation of dispersion-induced power fading for multi-service RoF linksbased on a phase-coherent orthogonal lightwave generator," Optics letters,vol. 40, pp. 2103-2106, 2015.
[22]. J. Sun,Z. Tan, T. Li, and M. Wang, "All‐optical correlator based on modaldispersion in multimode fiber," Optical Engineering, vol. 55, p. 031119,2015.
[21]. J. Nan,L. Tang-Jun, S. Jian, Z. Kang-Ping, and W. Mu-Guang^*,"Flatness of supercontinuum generated by a picosecond pulse in normaldispersion region of highly nonlinear fiber," JOURNAL OF INFRARED ANDMILLIMETER WAVES, vol. 34, pp. 196-202, 2015.
[20]. J. Sun,T.-j. Li, N. Jia, K.-p. Zhong, and W. Mu-Guang, "Experimentaldemonstration of 2× 80-Gbit/s OTDM multi-channel add-drop multiplexing in asingle fiber," in Real-time Photonic Measurements, Data Management, andProcessing, 2014, p. 927916.
[19]. J. Nan,L. Tang-Jun, S. Jian, Z. Kang-Ping, and W. Mu-Guang^*,"Coherence properties of supercontinuum generated by a picosecond pulse innormal dispersion region of highly nonlinear fiber," Acta Phys. Sin., vol.63, pp. 84203-084203, 2014.
[18]. J. Nan,L. Tang-Jun, S. Jian, Z. Kang-Ping, and W. Mu-Guang^*, "Simultaneous demultiplexing into two 10 Gbit/s using a bidirectionallyoperated highly nonlinear fiber," Acta Phys. Sin, vol. 63, pp.24201-024201, 2014.
[17]. H.-q.Mu, M.-g. Wang, and S.-s. Jian, "A cost-effective ultra-dense WDMPON system with speed of 12.5 Gbit/s and channel spacing of 12.5 GHz,"Optoelectronics Letters, vol. 10, pp. 455-458, 2014.
[16]. Z. Jing, W. Muguang*, and S. Chenguang, "Photonic frequency-multiplyingmillimeter-wave generation based on dual-parallel Mach-Zehnder modulator,"Acta Optica Sinica, vol. 3, pp. 71-78, 2014.
[15]. N. Jia,T. Li, J. Sun, K. Zhong, J. Li, and M. Wang*, "Simultaneoustwo-distributary-channel demultiplexing of an OTDM signal using abidirectionally operated highly nonlinear fiber after 100 km transmission,"Optics & Laser Technology, vol. 59, pp. 32-35, 2014.
[14]. 钟康平, 李唐军, 孙剑, 贾楠, 王目光, "基于线性相位插值的增强型载波相位估计算法," 光学学报, pp. 89-96, 2013.
[13]. K.-p.Zhong, T.-j. Li, N. Jia, J. Sun, and M. G. Wang, "An improvedmultiplier-free feed-forward carrier phase estimation for dual-polarizationQPSK modulation format," Optoelectronics Letters, vol. 9, pp. 305-308,2013.
[12]. K. P.Zhong, T. J. Li, S. Jian, N. Jia, and M. G. Wang,"Linewidth-Tolerant and Low Complexity Carrier Phase Estimation Based onPhase Linear Interpolation," in Asia Communications and PhotonicsConference, 2013, p. AW3F. 3.
[11]. M. Wang* and J. Yao*, "Tunable 360photonic radio-frequency phase shifter based on polarization modulation andall-optical differentiation," Journal of Lightwave Technology, vol. 31,pp. 2584-2589, 2013.
[10]. M. Wang* and J. Yao*, "Tunable opticalfrequency comb generation based on an optoelectronic oscillator," IEEEPhotonics Technology Letters, vol. 25, pp. 2035-2038, 2013.
[9].M. Wang* and J.Yao*, "Optical vector network analyzer based on unbalanced double-sidebandmodulation," IEEE Photonics Technology Letters, vol. 25, pp. 753-756,2013.
[8].M. Wang*, Y. Fu,C. Shao, T. Li, and S. Jian, "All-Optical Analog-to-Digital ConversionBased on Polarization Modulation and Wavelength-Dependent Birefringence,"Applied Physics Express, vol. 6, p. 092201, 2013.
[7].M. Wang^*, and J. Yao*, "Multitap Microwave Photonic FilterWith Negative Coefficients Based on the Inherent Birefringence in a (FormulaNot Shown) Phase Modulator," IEEE PHOTONICS JOURNAL, vol. 5, pp.550, 2013.
[6]. W. Liu, M. Wang, and J. Yao*, "Tunablemicrowave and sub-terahertz generation based on frequency quadrupling using a singlepolarization modulator," Journal of Lightwave Technology, vol. 31, pp.1636-1644, 2013.
[5]. L. Gao, M. Wang, X.-f. Chen, and J. Yao,"Frequency-and phase-tunable optoelectronic oscillator," IEEEPhotonics Technol. Lett, vol. 25, pp. 1011-1013, 2013.
[4].M. Wang^*, T. J. Li, S. S. Jian , “Analytical theory of pulsebroadening due to polarization mode dispersion and polarization dependentloss”, Optics Communications, 223(1-3), 75-80, 2003.
[3].M. Wang^*, T. J. Li, S. S. Jian , “A novel adjustable PMDcompensator based on a tapered high-birefringence linearly chirped fiber Bragggrating”, Optics Communications, 240(4-6), 307-314, 2004.
[2].M. Wang^*, T. J. Li, S. S. Jian , “Analytical theory forpolarization mode dispersion of the spun and twist fiber”, Opt. Express 11(9),2403-2410, 2003.
[1].M. Wang^*, T. J. Li, S. S. Jian, “Tunable PMD compensator based onhigh-birefringence linearly chirped FBG with cantilever beam”, Opt. Express,11(9), 2354-2363, 2003.





专著/译著 光波技术基础，清华大学出版社、北京交通大学出版社 2018 (合著)
光纤通信原理，清华大学出版社、北京交通大学出版社 2015(合著)



专利 Selected Patents
基于光电振荡器的干涉型光纤振动传感解调系统和方法
用于测量磁场的光电振荡器及其测量方法
一种用于测量湿度的光电振荡器及其测量方法
基于宽带可调谐光电振荡器的角速度测量装置和方法
基于可调谐光电振荡器的角速度测量装置
基于光电振荡器的角速度测量方法和装置
基于双驱M-Z型调制器的全光模数转换结构及实现方法
一种光时分复用器及制作方法
用于取样光纤光栅制作的振幅掩模板的制作方法
利用高双折射均匀光纤光栅补偿偏振模色散的方法和结构
一种制作大偏振模色散光纤光栅的装置
一种制作大偏振模色散非线性光纤光栅的装置



软件著作权


获奖与荣誉 詹天佑科技专项奖 2014
北京交通大学五四奖章 2014
北京高校青年英才计划 2013
教育部新世纪优秀人才计划 2010
首批红果园双百人才计划 2009
北京市科技新星 2008




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