1.个人简介

李明，男，博士，研究员，博士生导师，所务委员，光电子材料与器件重点实验室主任。获得了国家自然科学基金优青、杰青以及国家重点研发计划项目资助，发表期刊论文210余篇，其中以第一/通讯（含共同）作者发表Nature子刊8篇（1篇Nature Photonics，4篇Nature Communications，3篇Light:Science & Applications）。先后获得中国光学工程学会科学技术奖一等奖2项（排名第1、第5）、中国通信学会科学技术一等奖1项（排名第7）和二等奖1项（排名第2）、中国电子学会“优秀科技工作者”称号和中国科学杂志社Science Bulletin杰出贡献奖等。

2.主要科研方向

（1）光电集成芯片

（2）新型光电振荡器

（3）光电智能计算

3.主要学术成就

针对传统电子技术面临的“带宽瓶颈”问题，围绕光电集成芯片、新型光电振荡器和光电智能计算等前沿技术开展了一系列研究，主要成果包括：

1. 光电集成芯片：开展硅基光电子器件联合仿真技术研究，通过多平台软件交互建立了光电子器件仿真模型和集成高速通信系统端到端仿真模型。为北方集成电路技术创新中心（北京）有限公司开发12英寸硅基异质集成工艺平台的全套工艺设计套件（PDK），包含26类94颗硅光子器件，促进我国硅光量产代工能力的自主可控发展；开展高性能光电子器件的设计与封测技术开发，包括窄线宽激光器、大功率激光器、宽频带调制器等，利用相关技术与珠海光库科技股份有限公司、福建中科光芯光电科技有限公司建立光电子芯片设计封装技术联合实验室，共同推动我国通信用光电子核心器件技术与产业的发展；在CMOS兼容的工艺平台上实现了Driver、调制器、探测器和TIA的4通道集成收发阵列芯片，开发了4×112 Gbps的硅基高速光电子集成收发芯片，促进我国高端光通信与互连芯片集成技术实现突破。

2. 新型光电振荡器：发现了光电振荡器中振荡模式建立时间限制的规律，基于此规律提出了可快速扫频的新型傅里叶域锁模光电振荡器，为研制超宽带、可重构扫频光电振荡器微波源提供了重要的理论基础（Nature Communications, 9:1839, 2018），西班牙瓦伦西亚理工大学Jose Capmany 教授（IEEE/OSA Fellows）在Science Bulletin 上撰写了高亮评述文章，认为该工作“突破了光电振荡器模式建立时间的限制”；首次观测到光电混合系统中的宇称-时间对称现象，利用宇称-时间对称物理机理解决了光电振荡器高精细选模难题，为研制超低相噪光电振荡器提供了一种新途径（Light: Sciences & Applications, 7:38, 2018），荷兰特温特大学激光物理与非线性光学研究主席David Marpaung 教授认为该工作“克服了长期存在的严重限制光电振荡器发展的模式竞争和模式选取难题”；揭示了光电振荡器宽带随机振荡的新机理，基于此机理提出了环腔开放的新型随机光电振荡器，为研制超宽带随机微波信号源提供了一种新方案（Nature Communications，11：5724, 2020）；揭示了光电混合谐振腔内的参量频率转换机理，基于此机理提出了新型光电参量振荡器，为研制高性能光电混合计算的伊辛机提供了一种新方案（Light: Science & Applications, 9:102, 2020）；发现了集成化光电振荡器中光、电、热等多物理场耦合规律及串扰抑制机理，攻克了光电子芯片与射频芯片的异质异构集成难题，实现了小型化的集成光电振荡器（MWP 2017，Postdeadline Paper），法国巴黎第十一大学Ines Ghorbel教授评价该工作是“最先进的GHz振荡器”（State of the art GHz oscillators）。

3.光电智能计算：研制了第一款可编程的光子模拟信号处理集成芯片，通过改变注入SOA的正反电流，改变通过SOA光信号的通断状态，从而实现光子集成器件等效结构的重构，可编程执行微分器、积分器与希尔伯特变换三种不同的功能，处理带宽达到25GHz（Nature Photonics，10：190，2016），Nature正刊题为“带宽瓶颈”文章评价：如微电子集成芯片打开了通往微型电脑的大门，该工作是光子微处理器发展的重要一步，其集成度可与第一款微电子集成芯片相比拟。首次提出了光电伊辛机，将伊辛问题通过二值相位自旋耦合方式编译到光电参量振荡的模型中，基于最小损耗原理实现了组合优化问题的求解（Light: Science & Applications, 11:333, 2022），该工作获得了全国颠覆性技术创新大赛总决赛最高奖项。研制出了一款超高集成度光学卷积处理器，将波分复用技术结合光多模干涉机理实现相关卷积核的重构，算力密度达到当前最高水平（Nature Communications, 14:3000, 2023）。

发表的论文清单如下:

[213] X. Meng, G. Zhang, N. Shi*, G. Li, J. Azana, J. Capmany, J. Yao, Y. Shen, N. Zhu and M. Li*, "Compact optical convolution processing unit based on multimode interference,” Nature Communications 14, 3000 (2023).

[212] Q. Cen, H. Ding, T. Hao, S. Guan, Z. Qin, J. Lyu, W. Li, N. Zhu, K. Xu, Y. Dai*, and M. Li*, “Large-scale coherent ising machine based on optoelectronic parametric oscillator,” Light: Science & Applications 11(1), 333 (2022).

[211] X. Meng, N. Shi*, G. Li, G. Zhang, W. Li, N. Zhu, and M. Li*, “On-demand reconfigurable incoherent optical matrix operator for real-time video image display,” Journal of Lightwave Technology 41(6), 1637-1648 (2023).
[210] G. Zhang, Q. Cen, T. Hao, X. Yin, X. Zi, N. Shi, W. Li, N. Zhu, and M. Li*, “Self-injection locked silica external cavity narrow linewidth laser,” Journal of Lightwave Technology, DOI: 10.1109/JLT.2023.3235105.

[209] X. Meng, N. Shi*, D. Shi, W. Li, M Li*, "Photonics-enabled spiking timing-dependent convolutional neural network for real-time image classification," Optics Express 30 (10), 16217-16228 (2022).

[208] T. Hao, H. Ding, W. Li, N. Zhu, Y. Dai*, M. Li*, "Dissipative microwave photonic solitons in spontaneous frequency-hopping optoelectronic oscillators," Photonics Research 10 (5), 1280-1289 (2022).

[207] L. Wang, T. Hao, X. Chen, M Guan, F. Li, G. Li, M. Li, N. Zhu, W. Li, "Simple method for microwave photonic temperature interrogation with high resolution and sensitivity, " Optics Lett 47 (18), 4750-4753 (2022).

[206] Y. Wei, J Cheng, Y. Wang, H. Zhou, J. Dong, D. Huang, F. Li, M. Li, PKA Wai, X. Zhang, "Strategy for Low‐Loss Optical Devices When Using High‐Loss Materials," Advanced Photonics Research 3 (9), 2200120 (2022).

[205] X. Fan, Y. Chen, X. Cao, S. Zhu, M. Li, N. Zhu, W. Li, "Photonic-assisted frequency downconverter with self-interference cancellation and fiber dispersion elimination based on stimulated Brillouin scattering," Optics Express 30 (17), 30149-30163 (2022).

[204] X. Fan, X. Cao,M. Li, N. Zhu, W. Li, "Photonic Generation of Multi-Band Phase-Coded Microwave Pulses by Polarization Manipulation of Optical Signals," J. Lightwave Technol. 40(3), 672-680 (2022).

[203] H. Ding, Q. Cen, K. Xu, M. Li*, Y. Dai*, "Observation of parity-time symmetry in time-division multiplexing pulsed optoelectronic oscillators within a single resonator," Photonics Research 10 (8), 1915-1923 (2022).

[202] Y. Jin, Y. Yang, H. Hong, X. Xiang, R. Quan, T. Liu, S. Zhang, N. Zhu, M. Li*, R. Dong*, “Quantum microwave photonics in radio-over-fiber systems,” Photonics Research 10 (7), 1669-1678 (2022).

[201] G. Li, D. Shi, L. Wang, Y. Xiao, M. Li, N. Zhu, W. Li, “Unambiguous measurement of AOA using a DDMZM,” Optics Communications 514, 128132 (2022).

[200] H. Wen*, J. Cui, H. Zhou, Y. Chen, Y. Jin, B. Xu, K. Zhai, J. Sun, Y. Guo, Y. Wu, W. Chen, W. Chen, X. Wang, N. Zhu, G. Lu, G. Ji, D. Zhou, Y. Cheng, D. Yang*, M. Li*, “100 Gb/s NRZ OOK signal regeneration using four-wave mixing in a silicon waveguide with reverse-biased pin junction,” Optics Express 30 (21), 38077-38094 (2022).

[199] Y. Yao, Y. Zhao, Y. Wei, F. Zhou, D. Chen, Y. Zhang, X. Xiao, M. Li, J. Dong, S. Yu, X. Zhang, “Highly Integrated Dual‐Modality Microwave Frequency Identification System,” Laser & Photonics Reviews 16 (10), 2200006 (2022).

[198] C. Zhang, C. Xu, Y. Jin, M. Li, W. Li, Y. Liu, H. Yuan, J. Bai, J. An, N. Zhu, “Narrow linewidth semiconductor laser with a multi-period-delayed feedback photonic circuit,” Optics Express 30 (9), 15796-15806 (2022).

[197] Y. Yang, Y. Jin, X. Xiang, T. Hao, W. Li, T. Liu, S. Zhang, N. Zhu, R. Dong*, M. Li*, “Single-photon microwave photonics,” Science Bulletin 67 (7), 700-706 (2022).

[196] J. Du, X. Fan, X. Cao,M. Li, N. Zhu, W. Li, “Transmission of dual-chirp microwave signal over fiber with suppression chromatic-dispersion-induced power-fading based on stimulated Brillouin scattering,” Optics Communications 508, 127787 (2022).

[195] Y. Xiao, Y. Dai, N. Shi, W. Li, N. Zhu, M. Li*, “Microwave-photonics iterative nonlinear gain model for optoelectronic oscillators,” Optics Express 30 (7), 12131-12149 (2022).

[194] Z. Gong, A. Bruch, F. Yang, M. Li, J. Lu, J. Surya, C. Zou, H .Tang, “Quadratic strong coupling in AlN Kerr cavity solitons,” Optics Letters 47 (4), 746-749 (2022).

[193] X. Cao, X. Fan, G, Li, M. Li, N. Zhu, W. Li, “A Filterless Photonic Approach for DFS and AOA Measurement Using a Push-Pull DPol-MZM,” IEEE Photonics Technology Letters 34(1), 19 – 22 (2022).

[192] L. Wang, Y. Zhang, D. Wang, T. Hao, Y. Chong, Y. Gu, G. Li, M. Li, X. Xiao, N. Zhu, W. Li, “Photonic Generation of Multi-Format Radar Waveforms Based on an Integrated Silicon IQ Modulator,” IEEE Journal of Selected Topics in Quantum Electronics 28(5), 6000207 (2022).

[191] S. Zhu, X. Fan, X. Cao. Y. Wang, N. Zhu, M. Li, W. Li, “Photonic Generation and Antidispersion Transmission of Background-Free Multiband Arbitrarily Phase-Coded Microwave Signals,” IEEE Transactions on Microwave Theory and Techniques 70(4), 2290-2298 (2022).

[190] F. Li, M. Guan, W. Lu, J. Du, X. Chen, M. Li, N. Zhu, W. Li, “Photonic Generation of Dual-Band Dual-Format Phase-Coded Microwave Signals,” IEEE Photonics Technology Letters, 34, 21, 1127-1130 (2022).

[189] C. Xu, B.Xu, Y.Jin, W.Chen, H.Wen, M. Li, N.Zhu, “A DFB Laser With Integrated Passive Region Suitable for PAM-4 Modulation Signal,” in IEEE Photonics Journal, vol. 14, no. 4, pp. 1-6, 1544406 (2022).

[188] L. Wang, T. Hao, M. Guan, G. Li, M. Li, N. Zhu, W. Li, “Compact Multi-Tone Microwave Photonic Frequency Measurement Based on a Single Modulator and Frequency-to-Time Mapping,” Journal of Lightwave Technology, vol. 40, no. 19, pp. 6517-6522, 1 Oct.1, 2022.

[187] T. Hao, Y.Yang, Y. Jin, X. Xiang, W. Li, N. Zhu, R. Dong, M. Li*, “Quantum Microwave Photonics,” Journal of Lightwave Technology, vol. 40, no. 20, pp. 6616-6625 (2022).

[186] L. Wang, T. Hao, G. Li, M. Li, N. Zhu and W. Li, “Microwave Photonic Temperature Sensing Based on Fourier Domain Mode-Locked OEO and Temperature-to-Time Mapping,” Journal of Lightwave Technology, vol. 40, no. 15, pp. 5322-5327 (2022).

[185] X. Chen , G.Li, D.Shi, L.Wang, J. Du, M. Li, N. Zhu, W. Li ,”Photonic Generation of Rectangular and Triangular Microwave Waveforms With Tunable Duty Cycle,” in IEEE Photonics Technology Letters, vol. 34, no. 7, pp. 371-374 (2022).

[184] X. Fan, J. Du, G. Li, M. Li, N. Zhu, W. Li, “RF Self-Interference Cancellation and Frequency Downconversion With Immunity to Power Fading Based on Optoelectronic Oscillation,” Journal of Lightwave Technology, vol. 40, no. 12, pp. 3614-3621, 15 (2022).

[183] S. Zhu, X. Fan, X. Cao, Y. Wang, N. Zhu, M. Li, W. Li, “Photonic Generation and Antidispersion Transmission of Background-Free Multiband Arbitrarily Phase-Coded Microwave Signals,” IEEE Transactions on Microwave Theory and Techniques, vol. 70, no. 4, pp. 2290-2298 (2022).

[182] G. Li, D. Shi, L. Wang, M. Li, N. Zhu, W. Li, “Photonic System for Simultaneous and Unambiguous Measurement of Angle-of-Arrival and Doppler-Frequency-Shift,” Journal of Lightwave Technology, vol. 40, no. 8, pp. 2321-2328 (2022).

[181] G. Li, T. Hao, W. Li, and M. Li*, "Bandwidth superposition of linearly chirped microwave waveforms based on a Fourier domain mode-locked optoelectronic oscillator," Optics Express vol. 29, no. 22, pp. 36977-36987, 2021.

[180] Y. Xiao, Y. Meng, T. Hao, N. Shi, W. Li, and M. Li*, "Ultra-fast full-field optical characterization of CW lasers based on optical frequency comb, wavelength-to-time mapping and phase-diversity," Optics Express, vol. 29, no. 24. Pp. 39874-39884, 2021.

[179] Z. Ge, Y. Xiao, T. Hao, W. Li and M. Li*, "Tb/s Fast Random Bit Generation Based on a Broadband Random Optoelectronic Oscillator," IEEE Photonics Technology Letters, vol. 33, no. 22, pp. 1223-1226, 2021

[178] Y. Meng, T. Hao, W. Li, N. Zhu, and M. Li*, “Microwave photonic injection locking frequency divider based on a tunable optoelectronic oscillator,” Optics Express, vol. 29, no. 2, pp. 684-691, 2021.

[177] Y. Li, T. Hao, G Li, L. Wang, W. Li, Y. Dai, and M. Li*, “Photonic generation of phase-coded microwave signals based on Fourier domain mode locking,” IEEE Photonics Technology Letters, vol. 33, no. 9, pp. 433-436, 2021.

[176] Y. Meng, Y. Xiao, W. Li, N. Shi, and M. Li*, “An Up/Downstream Shared Optical Beam Forming Network for Remote Phased Array Antenna,” IEEE Photonics Journal, vol. 13, no. 3, pp. 1-9, 2021.

[175] Z. Lin, S. Sun, J. Azaña, W. Li, and M. Li*, “High-speed serial deep learning through temporal optical neurons,” Optics Express, vol. 29, no. 13, pp. 19392-19402, 2021.

[174] D. Liu, J. Tang, Y. Meng, W. Li, N. Zhu, and M. Li*, “Ultra-low Vpp and high-modulation-depth InP-based electro–optic microring modulator,” Journal of Semiconductors, vol. 42, no. 8, 082301, 2021.

[173] H. S. Wen, B. R. Xu, K. P. Zhai, J. Z. Sun, J. Wang, X. H. Du, Y. Jin, W. Chen, W. Li, N. H. Zhu, and M. Li*, “Ultrahigh spectral resolution single passband microwave photonic filter,” Optics Express, vol. 29, no. 18, pp. 28725-28740, 2021.

[172] K. Zhao, J. Yang, M. Zhong, Q. Gao, Y. Wang, X. Wang, W. Shen, C. Hu, K. Wang, G. Shen, M. Li, J. Wang, W. Hu, Z. Wei, "Direct Polarimetric Image Sensor and Wide Spectral Response Based on Quasi‐1D Sb2S3 Nanowire." Advanced Functional Materials, vol. 31, no. 6, 2006601, 2021.

[171] D. Shi, G. Li, Z. Jia, J. Wen, M. Li, N. Zhu, and W. Li, "Accuracy enhanced microwave frequency measurement based on the machine learning technique," Optics Express, vol. 29, no. 13, 19515-19524, 2021.

[170] D. Shi, J. Wen, Z. Jia, G. Li, X. Wang, M. Li, N. Zhu, and W. Li, "Reconfigurable Photonic generation and transmission of multi-format radar signals," Optics Communications, vol. 488, 126855, 2021.

[169] J. Wen, D. Shi, Z. Jia, G. Li, X. Wang, M. Li, N. Zhu, and W. Li, "Precise Identification of Wideband Multiple Microwave Frequency Based on Self-Heterodyne Low-Coherence Interferometry," Journal of Lightwave Technology, vol. 39, no. 10, pp. 3169-3176, 2021.

[168] Z. Jia, G. Li, D. Shi, M. Li, N. H. Zhu, and W. Li, "Photonic Image Rejection Mixer Based on Polarization Manipulation of a Broadband Optical Source," IEEE Photonics Journal, vol. 13, no. 2, pp. 1-10, 2021.

[167] G. Li, D. Shi, Z. Jia, L. Wang, M. Li, N. H. Zhu, and W. Li, "Photonic Scheme for the Generation of Background-Free Phase-Coded Microwave Pulses and Dual-Chirp Microwave Waveforms," Photonics Journal, vol. 13, no. 2, pp. 1-8, 2021.

[166] L. Wang, T. Hao, G. Li, W. Sun, M. Li, N. Zhu, and W. Li, "Photonic Generation and Transmission of Dual-Band Dual-Chirp Microwave Waveforms at C-Band and X-Band with Elimination of Power Fading," IEEE Photonics Journal vol. 13, no. 1, pp. 1-9, 2021.

[165] X. Fan, S. Zhu, J. Du, M. Li, N. H. Zhu, and W. Li, "Photonic generation of quadruple bandwidth dual-band dual-chirp microwave waveforms with immunity to power fading," Optics Letters, vol. 46, no. 4, pp. 868-871, 2021.

[164] X. Fan, S. Zhu, Y. Xiao, M. Li, N. H. Zhu, and W. Li, "Generation and anti-dispersion transmission of quadrupling-bandwidth dual-chirp microwave waveform based on a polarization-division multiplexing Mach–Zehnder modulator," Optical Engineering, vol. 60, no. 2, 026105, 2021.

[164] Z. T. Ge, T. F. Hao, J. Capmany, W. Li, N. H. Zhu and M. Li*, “Broadband random optoelectronic oscillator,” Nature Communications, vol. 11, no. 1, pp. 5724, 2020.

[163] T. Hao, Q. Z. Cen, S. H. Guan, W. Li, Y. T. Dai, N. H. Zhu and M. Li*, “Optoelectronic parametric oscillator,” Light: Science & Applications, vol. 9, no. 1, 102, 2020.

[162] T. Hao, Y. Liu, J. Tang, Q. Cen, W. Li, N. H. Zhu, Y. Dai, J. Capmany, J. Yao and M. Li*, “Recent advances in optoelectronic oscillators,” Advanced Photonics, vol. 2, no. 4, 2020. (Invited Review Article)

[161] Y. Yang, X. Xiang, F. Hou, R. Quan, B. Li, W. Li, N. H. Zhu, T. Liu, S. Zhang, R. Dong and M. Li*, “Inherent resolution limit on nonlocal wavelength-to-time mapping with entangled photon pairs,” Optics Express, vol. 28, no. 5, pp. 7488-7497, 2020.

[160] X Xiang, R Dong, R Quan, Y Jin, Y Yang, M Li*, T Liu, S Zhang, “Hybrid frequency-time spectrograph for the spectral measurement of the two-photon state,” Optics Letters, vol. 45, no. 11, pp. 2993-2996, 2020.

[159] N. Shi, T. Hao, W. Li, N. H. Zhu, and M. Li*, “Dual-functional Transmitter for Simultaneous RF/LFM Signal Using a Monolithic Integrated DFB Array,” IEEE Photonics Technology Letters, vol. 32, no. 5, pp. 239-242, 2020.

[158] N. Shi, T. Hao, W. Li and M. Li*, “A Compact Multifrequency Measurement System Based on an Integrated Frequency-Scanning Generator,” Applied sciences, vol. 10, no.23, 8571, Nov. 2020. (Invited Article)

[157] J. Tang, B. Zhu, W. Zhang, M. Li, S. Pan and J. Yao, “Hybrid Fourier-domain mode-locked laser for ultra-wideband linearly chirped microwave waveform generation,” Nature communications, vol.11, no.1, 3814, 2020.

[156] L. Wang, G. Y. Li, T. Hao, S. Zhu, M. Li, N. H. Zhu and W. Li, “Photonic generation of multiband and multi-format microwave signals based on a single modulator,” Optics Letters, vol. 45, no. 22, pp. 6190-6193, 2020.

[155] S. Zhu, X. J. Fan, M. Li, N. H. Zhu and W. Li, “Dual-chirp microwave waveform transmitter with elimination of power fading for one-to-multibase station fiber transmission,” Optics Letters, vol. 45, no. 5, pp. 1285-1288, 2020.

[154] S. Zhu, X. J. Fan, B. R. Xu, W. H. Sun, M. Li, N. H. Zhu and W. Li, “Polarization Manipulated Fourier Domain Mode-Locked Optoelectronic Oscillator,” Journal of Lightwave Technology, vol. 38, no. 19, pp. 5270-5277, 2020.

[153] G. Y. Li, L. Wang, S. Zhu, M. Li, N. H. Zhu and W. Li, “Photonic Generation of Dual-Chirp Microwave Waveforms Based on a Tunable Optoelectronic Oscillator,” IEEE Photonics Technology Letters, vol. 32, no. 10, pp. 599-602, 2020.

[152] S. Zhu, X. J. Fan, M. Li, N. H. Zhu and W. Li, “Optically controlled multi-carrier phase-shift-keying microwave signal generation by using cross-polarization modulation in highly nonlinear fiber,” Optics Communications, vol. 469, 125805, 2020.

[151] J. Wen, D. F. Shi, Z. Y. Jia, M. Li, N. H. Zhu and W. Li, “Simultaneous microwave frequency conversion and idler filtering based on polarization manipulating of an amplified spontaneous emission source,” Optics and Laser Technology, vol. 131, 106388, 2020.

[150] D. F. Shi, J. Wen, S. Zhu, Z. Y. Jia, Z. Shi, M. Li, N. H. Zhu and W. Li, “Instantaneous microwave frequency measurement based on non-sliced broadband optical source,” Optics Communications, vol. 458, 124758, 2020.

[141] K. Zhao, J. Yang, M. Zhong, Q. Gao, Y. Wang, X. Wang, W. Shen, C. Hu, K. Wang, G. Shen, M. Li, J. Wang W. Hu, and Z. Wei， “Direct Polarimetric Image Sensor and Wide Spectral Response Based on Quasi-1D Sb2S3 Nanowire,” Advanced Functional Materials, 2006601, 2020.

[140] N. Shi, T. Hao, W. Li, N. Zhu, and M. Li*, “Dual-functional Transmitter for Simultaneous RF/LFM Signal Using a Monolithic Integrated DFB Array,” IEEE Photonics Technology Letters, vol.32, no. 5, pp. 239-242, 2020.

[139] G. Wang, T. Hao, W. Li, N. Zhu, M. Li*, "Detection of wideband low-power RF signals using a stimulated Brillouin scattering-based optoelectronic oscillator." Optics Communications, vol. 439, 15, pp. 133-136, 2019.

[138] N. Shi, X. Zhu, S. Sun, W. Li, N. Zhu, M. Li*, "Fast-Switching Microwave Photonic Filter Using an Integrated Spectrum Shaper." IEEE Photonics Technology Letters, vol. 31, no.3, pp. 269-272, 2019.

[137] S. Zhu, M. Li, X. Wang, N. Zhu, Z. Cao, W. Li, "Photonic generation of background-free binary phase-coded microwave pulses." Optics letters, vol, 44, no.1, pp. 94-97, 2019.

[136] T. Hao, J. Tang, N. Shi, W. Li, N. Zhu, and M. Li*, “Dual-chirp Fourier domain mode-locked optoelectronic oscillator,” Optics Letters, vol. 44, no. 8, pp. 1912-1915, 2019. (Highlighted as Editor's Pick)

[135] S. Zhu, M. Li, X. Wang, N. Zhu, W. Li, "1× N hybrid radio frequency photonic splitter based on a dual-polarization dual-parallel Mach Zehnder modulator." Optics Communications, vol. 431 10-13, 2019.

[134] S. Zhu, M. Li, N. Zhu, W. Li, "Chromatic-dispersion-induced power fading suppression technique for bandwidth-quadrupling dual-chirp microwave signals over fiber transmission." Optics letters, vol. 44, no. 4, pp. 923-926, 2019.

[133] Y. Xiao, S. Sun, W. Li, N. H. Zhu, and M. Li*, “Ultra-fast Wavemeter for CW Laser Based on Wavelength-to-Time Mapping,” Journal of Lightwave Technology. vol. 37, no. 11, pp. 2661-2667, 2018.

[132] T. Hao, Q. Cen, Y. Dai, J. Tang, W. Li, J. Yao, N. H. Zhu, and M. Li*, “Breaking the limitation of mode building time in an optoelectronic oscillator,” Nature Communications, vol. 9, 1839, 2018.

[131] Y. Liu, T. Hao, W. Li, J. Capmany, N. H. Zhu, and M. Li*, “Observation of parity-time symmetry in microwave photonics,” Light: Science & Applications, vol. 7, no. 1, pp. 38, 2018.

[130] T. Hao, J. Tang, D. Domenech, W. Li, N. H. Zhu, J. Capmany, and M. Li*, “Toward Monolithic Integration of OEOs: From Systems to Chips,” Journal of Lightwave Technology, vol. 36, no. 19, pp. 4565-4582, 2018. (Invited Article)

[129] N. Shi, T. Hao, W. Li, N. H. Zhu, and M. Li*, “A reconfigurable microwave photonic filter with flexible tunability using a multi-wavelength laser and a multi-channel phase-shifted fiber Bragg grating,” Optics Communications, vol. 407, pp. 27-32, 2018.

[128] M. Li*, S. Sun, B. Li, H. Asghari, Y. Deng, W. Li, and N. H. Zhu, “Time-bandwidth compression of microwave signals,” Optics Express, vol. 26, no. 2, pp. 990-999, 2018.

[127] H. Sun, X. Zhu, W. Li, N. H. Zhu, and M. Li*, “Real-Time Optical Spectrum Fourier Transform With Time–Bandwidth Product Compression,” IEEE Photonics Journal, vol. 10, no. 1, pp. 1-14, 2018.

[126] H. Sun, X. Zhu, W. Li, N. H. Zhu, and M. Li*, “Reconfigurable microwave signal processor with a phase shift of π,” Optics Express, vol. 26, no. 8, pp. 10358-10370, 2018.

[125] J. Tang, T. Hao, W. Li, D. Domenech, R. Baños, P. Muñoz, N. H. Zhu, J. Capmany, and M. Li*, “Integrated optoelectronic oscillator,” Optics Express, vol. 26, no. 9, pp. 12257-12265, 2018.

[124] S. Sun, Z. Lin, W. Li, N. H. Zhu, and M. Li*, “Time-stretch probing of ultra-fast soliton dynamics related to Q-switched instabilities in mode-locked fiber laser,” Optics Express, vol. 26, no. 16, pp. 20888-20901, 2018.

[123] T. Hao, J. Tang, W. Li, N. H. Zhu, and M. Li*, “Tunable Fourier domain mode locked optoelectronic oscillator using stimulated Brillouin scattering,” IEEE Photonics Technology Letters, vol.30, no.21, pp. 1842-1845, 2018. (Invited Article)

[122] T. Hao, J. Tang, W. Li , N. H. Zhu , and M. Li*, “Microwave photonics frequency-to-time mapping based on a Fourier domain mode locked optoelectronic oscillator,” Optics express, vol. 26, no. 26, pp. 33582-33591, 2018.

[121] H. S. Wen, M. Li, W. Li, and N. H. Zhu, “Ultrahigh-Q and tunable single-passband microwave photonic filter based on stimulated Brillouin scattering and a fiber ring resonator,” Optics Letters, vol. 43, no. 19, pp. 4659-4662, 2018.

[120] S. Zhu, Z. Shi, M. Li, N. H. Zhu, and W. Li, “Simultaneous frequency upconversion and phase coding of a radio-frequency signal for photonic radars,” Optics letters, vol. 43, no. 3, pp. 583-586, 2018.

[119] S. Zhu, M. Li, N. H. Zhu, and W. Li, “Transmission of dual-chirp microwave waveform over fiber with compensation of dispersion-induced power fading,” Optics letters, vol. 43, no. 11, pp. 2466-2469, 2018.

[118] S. Zhu, M. Li, X. Wang, N. H. Zhu, and W. Li, “Photonic Generation of Ultra-Wideband Signal by Truncating a Continuous Wave into a Pulse,” IEEE Photonics Technology Letters, pp. 1-1, 2018.

[117] L. Wang, M. Li, N. H. Zhu, and W. Li, “Switchable Microwave Photonic Filter between Dual-notch and Dual-passband Responses,” IEEE Photonics Technology Letters, pp. 1-1, 2018.

[116] Z. Shi, S. Zhu, M. Li, N. H. Zhu, and W. Li, “Reconfigurable microwave photonic mixer based on dual-polarization dual-parallel Mach–Zehnder modulator,” Optics Communications, vol. 428, pp. 131-135, 2018.

[115] S. Zhu, X. Wang, M. Li, N. H. Zhu, and W. Li, “A simple photonic method to generate square and triangular microwave waveforms,” Optics Communications, vol. 426, pp. 654-657, 2018.

[114] L. Wang, C. Yang, M. Li, N. Zhu, and W. Li, “Switchable microwave photonic filter based on a dual-parallel Mach–Zehnder modulator,” Applied optics, vol. 57, no. 16, pp. 4537-4541, 2018.

[113] W. Liu#, M. Li#, R. S. Guzzon#, E. J. Norberg, J. S. Parker, M. Lu, L. A. Coldren, and J. Yao, “An integrated parity-time symmetric wavelength-tunable single-mode microring laser,” Nature Communications, vol. 8, pp. 15389, 2017. (#Equal contributions)

[112] J. Hervás, A. L. Ricchiuti, W. Li, N. H. Zhu, C. R. Fernández-Pousa, S. Sales, M. Li*, and J. Capmany, “Microwave photonics for optical sensors,” IEEE Journal of Selected Topics in Quantum Electronics, vol. 23, no. 2, pp. 5602013, 2017. (Invited Review Article)

[111] M. Li, S. Sun, A. Malacarne, S. LaRochelle, J. Yao, N. Zhu, and J. Azana, “Reconfigurable single-shot incoherent optical signal processing system for chirped microwave signal compression,” Science Bulletin, vol. 62, no. 4, pp. 242-248, 2017. (Cover Story)

[110] N. Shi, T. Hao, W. Li, N. Zhu, and M. Li*, “A reconfigurable microwave photonic filter with flexible tunability using a multi-wavelength laser and a multi-channel phase-shifted fiber Bragg grating,” Optics Communications, vol. 407, pp. 27-32, 2018.

[109] Z. Shi, L. Wang, C. Yang, M. Li, N. H. Zhu, and W. Li, “Multifunctional microwave photonic signal processor based on dual-parallel Mach–Zehnder modulator and stimulated Brillouin scattering,” Optical Engineering, vol. 56, no. 9, pp. 096102, 2017.

[108] H. Yan, D. Han, M. Li, and B. Lin, “Relative humidity sensor based on surface plasmon resonance of D-shaped fiber with polyvinyl alcohol embedding Au grating,” Journal of Nanophotonics, vol. 11, no. 1, pp. 016008-016008, 2017.

[107] L. Zhang, M. Li*, N. Shi, X. Zhu, S. Sun, J. Tang, W. Li, and N. Zhu, “Photonic true time delay beamforming technique with ultra-fast beam scanning,” Optics Express, vol. 25, no. 13, pp. 14524-14532, 2017.

[106] W. Jun, L. Wang, C. Yang, M. Li, N. H. Zhu, J. Guo, L. Xiong, and W. Li, “Optical vector network analyzer based on double-sideband modulation,” Optics Letters, vol. 42, no. 21, pp. 4426-4429, 2017.

[105] X. Zou, M. Li, W. Pan, L. Yan, and L. Shao, “Multichannel Narrow, Flat-Top Optical Filters Based on Multiple-Phase-Shifted and Phase Sampled FBG,” IEEE Journal of Quantum Electronics, vol. 53, no. 1, pp. 6800205, 2017.

[104] W. Li, M. Li, N. Zhu “Photonic generation of background-free millimeter-wave ultra-wideband signals,” Chinese Optics Letters, 2016. Under Review (Invited Article)

[J103] N. Zhu, M. Li, Y. Hao, “Optoelectronic devices and integration technologies,” Scientia Sinica Informationis, vol. 46, no. 8, pp. 1156-1174, 2016. (Invited Article)

[J102] M. Li, N. Zhu, “Recent advances in microwave photonics,” Frontiers of Optoelectronics, vol. 9, no. 2, pp. 160-185, June 2016. (Invited Review Article)

[J101] X. Wang, W. Li, M. Li, N. Zhu, “Photonics generation of frequency-shift keying radio-frequency signal using nonlinear polarization rotation in a highly nonlinear fiber,” Optical Engineering, 2016. (Accepted for publication)

[J100] J. Tang, M. Li*, S. Sun, Z. Li, W. Li, and N. Zhu, "Broadband microwave photonic phase shifter based on a feedback-coupled microring resonator with small radio frequency power variations," Optics Letters, vol. 41, no. 20, pp. 4609-4612, 2016

[J99] Y. Deng, M. Li, N. Shi, J. Tang, S. Sun, L. Zhang, W. Li, N. Zhu, “Fully Characterization of an Active Optical Filter Based on an Equivalent-Phase-Shifted DFB-SOA,” Optics Communications, vol. 376, pp. 1-5, 2016.

[J98] N. Shi, M. Li*, Y. Deng, L. Zhang, S. Sun, J. Tang, W. Li & N. Zhu, “Experimental Demonstration of a Multi-Target Detection Technique Using an X-band Optically Steered Phased Array Radar,” Optics Express, vol. 24, no. 13, pp. 14438-14450, 2016.

[J97] W. Liu, B. Romeira, M. Li, R. S. Guzzon, E. J. Norberg, J. S. Parker, L. A. Coldren, J. P. Yao, "A wavelength tunable optical buffer based on self-pulsation in an active microring resonator,"  Journal Lightwave Technology, under revisions.

[J96] S. Sun, M. Li, J. Tang, N. Zhu, T. J. Ahn, J. Azana, “Femtosecond pulse shaping using wavelength-selective directional couplers: proposal and simulation,” Optics Express, vol. 24, no. 8, pp. 7943-7950, 2016.

[J95] W. Liu#, M. Li#, R. S. Guzzon#, E. J. Norberg, J. S. Parker, M. Lu, L. A. Coldren, and J. P. Yao, "A fully reconfigurable photonic integrated signal processor," Nature Photonics, vol. 10, no. 3, pp. 190-195, 2016 (#Equal Contribution)

[J94] M. Li, Y. Deng, J. Tang, S. Sun, J. Yao, J. Azaña, and N. H. Zhu, "Reconfigurable optical signal processing based on a distributed feedback semiconductor optical amplifier," Scientific Reports, vol. 6, 2016.

[J93] M. Burla, X. Wang, M. Li, L. Chrostowski, and J. Azana, "Wideband dynamic microwave frequency identification system using a low-power, ultra-compact silicon photonic chip," Nature Communications, vol. 7, pp. 13004, 2016

[J92] W. Wang, M. Li*, S. Sun, C. Wang, Y. Deng, and N. H. Zhu, "Background-free microwave signal generation based on temporal pulse shaping system," IEEEPhotonics Technology Letters, vol. 28, no. 8, pp. 903-906, 2016.

[J91] N. Jia, H. T. Yan, M. Li*, "Dual-pulse pumped for Enhancing Supercontinuum Generation," IEEE Photonics Journal, vol. 8, no. 1, pp. 1943-0655, 2016.

[J90] M. Li and N. H. Zhu, "Microwave photonics in China," IEEE Photonics Society Newsletter, Feb. 2016. (Invited Review Article)

[J89] M. Li, X. Chen, Y. Su, X. Wang, M. Chen, D. Dai, J. Liu, and N. H. Zhu, "Photonic Integration Circuits in China," IEEE Journal of Quantum Electronics, 2015, Accepted for Publication, DOI: 10.1109/JQE.2015.2504087. (Invited Review Article)

[J88] S. Sun, Y. Deng, N. Huang, J. Tang, N. Zhu and M. Li*, “A tunable photonic temporal integrator with ultra-long integration time windows based on Raman-gain assisted phase-shifted silicon Bragg gratings” Optics Communications, vol. 373, pp. 91-94, 2016.

[J87] M. Li, "Taming electric discharges using optical beams," Science Bulletin, vol. 2, pp. 114, 2016. (Research Highlight)

[J86] W. Li, C.W. Yang, L. Wang, Z.L. Yuan, J.G. Liu, M. Li, and N.H. Zhu, "Microwave photonic bandstop filter with wide tunability and adjustable bandwidth," Optics Express, vol. 23, no. 26, pp. 33579-33586, 2015.

[J85] A. Malacarne, Y. Park, M. Li, S. LaRochelle and J. Azaña, "Real-time Fourier transformation of lightwave spectra and application in optical reflectometry," Optics Express, vol. 23, no. 25, pp. 32516-32527, 2015.

[J84] Y. Deng, M. Li*, T. Jian, S. Sun, N. Huang, and N. H. Zhu, “Widely tunable single passband microwave photonic filter based on DFB-SOA-assisted optical carrier recovery,” IEEE Photonics Journal, vol. 7, no. 5, 2015.

[J83] S. Sun, Y. Deng, N. Zhu and M. Li*, “Tunable fractional-order photonic differentiator using a DFB-SOA” Optical Engineering, vol. 55, no. 3, 2015.

[J82] M. Li*, W. Liu, N. Huang, R. S. Guzzon, N. Zhu, J. Azaña, L. A. Coldren and J. Yao, "Advances in all-optical circuits," Optics & Photonics News, Mar. 2015. (Invited Article)

[J81] R. Maram, J. Howe, M. Li, and J. Azaña, "Lossless fractional repetition-rate multiplication of optical pulse trains," Opt. Letters, vol. 40, pp. 375-378, 2015.

[J80] R. Maram, J. Howe, M. Li, and J. Azaña, "Noiseless intensity amplification of repetitive signals by coherent addition using the temporal Talbot effect," Nature Communications, vol. 5, no. 5163, 2014.

[J79] M. Li*, J. Azana, N. H. Zhu, and J. P. Yao, "Recent progresses on optical arbitrary waveform generation," Frontiers of Optoelectronics, vol. 7, no. 3, pp. 359-375, 2014. (Invited Review Article)

[J78] M. Li*, J. Azana, and J. P. Yao, "Preface on special topic: all-optical signal processing," Chinese Science Bulletin, vol. 59, no. 22, pp. 2647-2648, 2014.

[J77] M. Burla, L. R. Cortés, M. Li, X. Wang, L. Chrostowski, and J. Azana, "On-chip programmable ultra-wideband microwave photonic phase shifter and true time delay unit," Opt. Letters, vol. 39, no. 21, pp. 6181-6184, 2014.

[J76] M. Burla, M. Li*, L. R. Cortés, X. Wang, M. R. Fernández-Ruiz, L. Chrostowski, and J. Azana, "Terahertz-bandwidth photonic fractional Hilbert transformer based on a phase-shifted waveguide Bragg grating on silicon," Opt. Letters, vol. 39, no. 21, pp. 6241-6244, 2014.

[J75] Y. Deng, M. Li*, N.B. Huang, and N. H. Zhu, "Ka-Band tunable flat-top microwave photonic filter using a multi-phase-shifted fiber Bragg grating," IEEE Photonics Journal, vol. 6, no. 4, pp. 1-8, 2014.

[J74] X. H. Zou, M. Li, W. Pan, B. Luo, L.S. Yan, and L.-Y. Shao, "Optical length change measurement via RF frequency shift analysis of incoherent light source based optoelectronic oscillator," Optics Express, vol. 22, no. 9, pp. 11129-11139, 2014.

[J73] Y. Deng, M. Li*, N.B. Huang, Jose Azana and N. H. Zhu, "Optical length change measurement based on an incoherent single bandpass microwave photonic filter with high resolution," OSA Photonics Research, vol. 2, no. 4, pp. B35-B39, 2014.

[J72] Y. Deng, M. Li*, N.B. Huang, Jose Azana and N. H. Zhu, "Serial time-encoded amplified microscopy for ultrafast imaging based on multi-wavelength laser," Chinese Science Bulletin, vol. 59, no. 22, pp. 2693-2701, 2014.(Cover Paper)

[J71] W. Liu, M. Li, R. S. Guzzon, E. J. Norberg, J. S. Parker, L. A. Coldren, and J. P. Yao, "Photonic temporal integrator with an ultra-long integration time window based on an InP-InGaAsP integrated ring resonator," IEEE/OSA Journal of Lightwave Technology, vol. 32, no. 20, pp. 3654-3659, 2014.

[J70] J. J. Guo, M. Li*, Y. Deng, N. B. Huang, J. G. Liu, and N. H. Zhu, "Multichannel optical filters with an ultranarrow bandwidth based on sampled Brillouin dynamic gratings," Optics Express, vol. 22, no. 4, pp. 3105-3116, 2014.

[J69] N. B. Huang, M. Li*, Y. Deng, and N. H. Zhu, "Optical pulse generation based on an optoelectronic oscillator with cascaded nonlinear semiconductor optical amplifiers," IEEE Photonics Journal, vol. 6, no. 1, pp. 5500208 (1-8), 2014.

[J68] N. B. Huang, M. Li*, R. Ashrafi, L. Wang, X. Wang, J. Azaña and N. H. Zhu, "Active Fabry-Perot cavity for photonic temporal integrator with ultra-long operation time window," Optics Express, vol. 22, no. 3, pp. 3105-3116, 2014.

[J67] X. H. Zou, M. Li, W. W. Ge, W. Pan, B. Luo, L. S. Yan, and J. Azaña, "Synthesis of fiber Bragg gratings with arbitrary stationary power/field distribution," IEEE Journal of Quantum Electronics, vol. 50, no. 3, pp. 186-197, 2014.

[J66] W. Li, L.X. Wang, J.Y. Zheng, M. Li, N.H. Zhu, "Photonic generation of ultrawideband signals with large carrier frequency tunability based on an optical carrier phase-shifting method," IEEE Photonics Journal, vol. 5, no. 5, pp. 5502007, 2013.

[J65] H Wang, JY Zheng, W Li, LX Wang, M Li, L Xie, NH Zhu, "Widely tunable single-bandpass microwave photonic filter based on polarization processing of a nonsliced broadband optical source," Opt. Letters, vol. 38, no. 22, pp. 4857-4860, 2013.

[J64] J. Y. Zheng, N.H. Zhu, L.X. Wang, M. Li, H. Wang, W. Li, X. Q. Qi, and J. G. Liu, "Spectral sculpting of chaotic-UWB signals using a dual-loops optoelectronic oscillator," Photonics Technology Letters, vol. 25, pp. 2397-2400, 2013.

[J63] M. Burla, L. R. Cortés, M. Li, X. Wang, L. Chrostowski, and J. Azaña, "Integrated waveguide Bragg gratings for microwave photonics signal processing," Optics Express, vol. 21, pp. 25120-25147, 2013. (Invited Review Article, Top Download in October 2013)

[J62] M. Li, "My Research Life in Canada: A Tale of Two Labs," Optics and Photonics News, April, 2013. (Invited Article)

[J61] X. Zou, M Li, W Pan, L Yan, J Azana, J Yao，"All-fiber optical filter with an ultranarrow and rectangular spectral response," Opt. Letters, vol. 38, no. 16, 3096-3098, 2013. (Top Download in August and September 2013)

[J60] B Li, M Li, S Lou, J Azaña，"Linear optical pulse compression based on temporal zone plates," Opt.express, vol. 21, no. 14, 16814-16830 (2013).

[J59] R. Ashrafi, M. Li, and J. Azana, "Multi-TBaud optical coding based on superluminal space-to-time mapping in long period gratings," Scientific Research, vol. 3, no. 2, pp. 126, 2013.

[J58] W. Li, L. X. Wang, M. Li, and N. H. Zhu, "Photonic generation of widely tunable and background-free binary phase-coded RF pulses," Opt. Letters, vol. 38, no. 17, pp. 3441-3444, 2013.

[J57] W. Li, L. X. Wang, M. Li, and N. H. Zhu, “Single phase modulator for binary phase-coded microwave signals generation with large carrier frequency tunability” IEEE Photonics Technology Letters., vol. 25, no. 19, pp. 1867-1870, 2013.

[J56] W. Li, L. X. Wang, J. Y. Zheng, M. Li, and N. H. Zhu, "Photonic MMW-UWB signal generation via DPMZM-based frequency up-conversion,” IEEE Photonics Technology Letters., vol. 25, no. 19, pp. 1875-1878, 2013.

[J55]W. Li, L. X. Wang, M. Li, H. Wang, and N. H. Zhu, "Photonic generation of binary phase-coded microwave signals with large frequency tunability using a dual-parallel Mach–Zehnder modulator,” IEEE Photon. J., vol. 5, no. 4, pp.5501507, Aug. 2013.

[J54]M. R. Fernandez, M. Li, and J. Azaña, " Time-domain holograms for generation and processing of temporal complex information by intensity-only modulation processes " Optics Express, vol. 21, no. 8, pp. 10314-10323, 2013.

[J53] M. R. Fernandez, M. Li, et al, "Picosecond optical signal processing based on transmissive fiber Bragg gratings," Opt. Letters, vol. 38, no. 8, pp. 1247-1249, 2013.

[J52] R. Ashrafi, M. Li et al, "Experimental demonstration of superluminal space-to-time mapping in long period gratings," Opt. Letters, vol. 38, no. 9, pp. 1419-1421, 2013.

[J51] R. Ashrafi, M. Li, and J. Azaña, "Tsymbol/s optical coding based on long period gratings," IEEE Photonics Technology Letters, vol. 25, no. 10, pp. 910-913, 2013.

[J50] R. Ashrafi, M. Li, and J. Azaña, “Coupling-strength-independent long-period grating designs for THz-bandwidth optical differentiators,” IEEE Photonics Journal, vol. 5, no. 2, pp. 7100311, 2013.

[J49] R. Ashrafi, M. Li, S. LaRochelle, and J. Azaña, "Superluminal space-to-time mapping in grating-assisted co-directional couplers," Optics Express, vol. 21, pp. 6249-6256, 2013.

[J48] Y. Hu, M. Li, D. Bongiovanni, M. Clerici, J. Yao, Z. Chen, J. Azaña, and R. Morandotti, "Spectrum to distance mapping via nonlinear Airy pulses," Opt. Letters, vol. 38, pp. 380-382, 2013.

[J47] M. Li, H.-S. Jeong,J. Azaña, and T.-J. Ahn, "25-terahertz-bandwidth all-optical temporal differentiator," Optics Express, vol. 20, no. 27, pp. 28273–28280, Dec. 2012.

[J46] M. Li, Z. Li, and J. P. Yao, "Photonic generation of a precisely pi phase shifted binary phase-coded microwave signal," IEEE Photonics Technology Letters., vol. 24, no. 22, pp. 2001-2004, Nov. 2012.

[J45] M. Li, W. Li, and J. P. Yao, "A tunable optoelectronic oscillator based on a high-Q spectrum-sliced photonic microwave transversal filter," IEEE Photonics Technology Letters., vol. 24, no. 14, pp. 1251-1253, July. 2012.

[J44] M. Li, P. Dumais, R. Ashrafi, H. P. Bazargani, J.-B. Quélène, C. Callender, and J. Azaña, "Ultrashort flat-top pulse generation using on-chip CMOS-compatible Mach-Zehnder interferometers," IEEE Photonics Technology Letters., vol. 24, no. 16, pp. 1387-1389, Aug. 2012.

[J43] M. Li and J. P. Yao, "Ultrafast all-optical wavelet transform based on temporal pulse shaping incorporating a two-dimensional array of cascaded linearly chirped fiber Bragg gratings," IEEE Photonics Technology Letters., vol. 24, no. 15, pp. 1319-1321, Aug. 2012.

[J42] A. Malacarne, R. Ashrafi, M. Li, S. LaRochelle, J. P. Yao, and J. Azaña, "Single-shot photonic time-intensity integration based on a time-spectrum convolution system," Optics Letters., vol. 37, no. 8, pp. 1355-1357, Apr. 2012.

[J41] W. Li, M. Li, and J. P. Yao, "A narrow-passband and frequency-tunable micro-wave photonic filter based on phase-modulation to intensity-modulation conversion using a phase-shifted fiber Bragg grating," IEEE Trans. Microw. Theory Tech., vol. 60, no. 5, pp. 1287-1296, May 2012.

[J40] Z. Li, M. Li, H. Chi, X. Zhang, and J. P. Yao, "Photonic generation of phase-coded millimeter-wave signal with large frequency tunability using a polarization-maintaining fiber Bragg grating," IEEE Microwav. Wireless Compon. Lett., vol. 21, no. 12, pp. 694-696, Dec. 2011.

[J39] M. Li and J. P. Yao, "Photonic generation of continuously tunable chirped microwave waveforms based on a temporal interferometer incorporating an optically-pumped linearly-chirped fiber Bragg grating," IEEE Trans. Microw. Theory Tech., vol. 50, no. 12, pp. 3531-3537, Dec. 2011.

[J38] M. Li and J. P. Yao, "All-optical short-time Fourier transform based on a temporal pulse shaping system incorporating an array of cascaded linearly chirped fiber Bragg gratings," IEEE Photonics Technology Letters., vol. 23, no. 20, pp. 1439-1441, Oct. 2011.

[J37] M. Li and J. P. Yao, "Multichannel arbitrary-order photonic temporal differentiator for wavelength-division-multiplexed signal processing using a single fiber Bragg grating," IEEE/OSA Journal of Lightwave Technology., vol. 29, no. 17, pp. 2506-2511, Sep. 2011.

[J36] W. Liu, M. Li, C. Wang, and J. P. Yao, "Real-time interrogation of a linearly chirped fiber Bragg grating sensor with improved resolution and signal-to-noise ratio," IEEE/OSA Journal of Lightwave Technology., vol. 29, no. 9, pp. 1239-1247, May 2011.

[J35] Y. Han, Z. Li, S. Pan, M. Li, and J. P. Yao, "Photonic-assisted tunable microwave pulse fractional Hilbert transformer based on a temporal pulse shaping system," IEEE Photonics Technology Letters., vol. 23, no. 9, pp. 570-572, May 2011.

[J34] H. Shahoei, M. Li , and J. P. Yao, "Continuously tunable time delay using an optically pumped linearly chirped fiber Bragg grating," IEEE/OSA Journal of Lightwave Technology., vol. 29, no. 10, pp. 1465-1472, May 2011.

[J33] M. Li, Y. Han, S. Pan, and J. P. Yao, "Experimental demonstration of symmetrical waveform generation based on amplitude-only modulation in a temporal pulse shaping system," IEEE Photonics Technology Letters., vol. 23, no. 11, pp. 715-717, Jun. 2011.

[J32] M. Li, L.Y. Shao, J. Albert and J. P. Yao, "Tilted fiber Bragg grating for chirped microwave waveform generation," IEEE Photonics Technology Letters., vol. 23, no. 5, pp. 314-316, Mar. 2011.

[J31] M. Li, L.Y. Shao, J. Albert and J. P. Yao, "Continuously tunable photonic fractional temporal differentiator based on a tilted fiber Bragg grating," IEEE Photonics Technology Letters., vol. 23, no. 4, pp. 251-253, Feb. 2011.

[J30] Z. Li, C. Wang, M. Li, H. Chi, X. M. Zhang and J. P. Yao, "Instantaneous microwave frequency measurement using a special fiber bragg grating," IEEE Microwave Theory and Wireless Component Letters., vol. 21, no. 1, Jan. 2011.

[J29] M. Li, C. Wang, W. Li, J. Yao, "An unbalanced temporal pulse shaping system for chirped microwave waveform generation," IEEE Trans. Microw. Theory Tech., vol. 58, no. 11, pp. 2968-2975, Nov. 2010.

[J28] M. Li, J. Yao, “Experimental demonstration of a wideband photonic temporal Hilbert transformer based on a single fiber Bragg grating,” IEEE Photonics Technology Letters., vol. 22, no. 21, pp. 1559-1561, Dec. 2010.

[J27] C. Wang, M. Li, J. Yao, "Continuously tunable photonic microwave frequency multiplication by use of an unbalanced temporal pulse shaping system," IEEE Photonics Technology Letters., vol. 22, no. 17, pp. 1285-1287, Aug. 2010.

[J26] X. Chen, T. Kameyama, M. Li, H. Li, “Multiple dual-wavelengths fiber ring laser utilizing a phase-only sampled fiber Bragg grating with multiple phase-shifts inserted,” Appl. Phys. B - Lasers and Optics, vol. 101, no. 1-2, pp. 115-118, Apr. 2010.

[J25] M. Li, J. Yao, "All-fiber temporal photonic fractional Hilbert transformer based on a directly designed fiber Bragg grating," Optics Letters., vol. 35, no.2 , pp. 223-225, 2010.

[J24] M. Li, D. Janner, J. Yao, and V. Pruneri, “Arbitrary-order all-fiber temporal differentiators based on fiber Bragg gratings: design and experimental demonstration,” Optics Express, vol. 17, no. 22, pp. 19798–19807, 2009.

[J23] M. Li, X. Chen, T, Fuji, Y. Kudo, H. Li, and Y. Painchaud, “Multiwavelength fiber laser based on the utilization of a phase-shifted phase-only sampled fiber Bragg grating,” Optics Letters., vol. 34, no. 11, pp. 1717-1719, 2009.

[J22] H. Li, M. Li, and J. Hayashi, “Ultrahigh channel-count phase-only sampled fiber Bragg grating covering the S-, C- and L- band,” Optics Letters., vol. 34, no. 7, pp. 938-940, 2009.

[J21] M. Li, T. Fujii, and H. Li, “Multiplication of a multi-channel notch filter based on a phase shifted phase-only sampled fiber Bragg grating,” IEEE Photonics Technology Letters., vol. 21, no. 13, pp. 926-928, 2009.

[J20] M. Li, X. Chen, J. Hayashi, and H. Li, “Advanced design of the ultrahigh-channel-count fiber Bragg grating based on the double sampling method,” Optics Express, vol. 17, no.10, pp. 8382-8394, 2009.

[J19] M. Li, H. Li, and Y. Painchaud, “Proposal and realization for a broadband all-fiber non-uniformly spaced multi-channel optical filter,” Optics Communications, vol. 282, pp. 879-882, 2009.

[J18] M. Li, J. Hayashi, and H. Li, “Advanced design of complex fiber Bragg grating for multi-channel triangular filter,” J. Opt. Soc. Am. B, vol. 26, no. 2, pp. 228-234, 2009.

[J17] M. Li and H. Li, “Influences of writing-beam size on the performances of dispersion-free multi-channel fiber Bragg grating,” Opt. Fiber Technol., vol. 15, no. 1, pp. 33-38, 2009.

[J16] M. Li, H. Li, and Y. Painchaud, "Multi-channel notch filter based on a phase-shift phase-only sampled fiber Bragg grating," Optics Express, vol. 16, no. 23, pp. 19388-19394, 2008.

[J15] M. Li, H. Li, “Correction to ``Chromatic dispersion measurement for multichannel FBG based on a novel asymmetrical Sagnac loop interferometer,'' IEEE Photonics Technology Letters., vol. 20, no. 3, pp. 226-226, 2008.

[J14] M. Li, T. Takahagi, K. Ogusu, H. Li, and Y. Painchaud, “A comprehensive study of the chromatic dispersion measurement of the multi-channel fiber Bragg grating based on an asymmetrical Sagnac loop interferometer,” Optics Communications, vol. 281, pp. 5165-5172, 2008.

[J13] M. Li, H. Li, “Reflection equalization of the simultaneous dispersion and dispersion-slope compensation based on a phase-only sampled fiber Bragg grating,” Optics Express, vol. 16, no. 13, pp. 9821-9828, 2008.

[J12] M. Li and H. Li, “Chromatic dispersion measurement for multi-channel FBG based on a novel asymmetrical Sagnac loop interferometer,” IEEE Photonics Technology Letters., vol. 19, no. 20, pp.1601-1603, 2007.

[J11] H. Li, M. Li, Y. Sheng, and J. E. Rothenberg, “Advances in the design and fabrication of high channel-count fiber Bragg gratings,” Journal of Lightwave Technology., vol. 25, no. 9, pp. 2739-2749,2007. (Invited Tutorial)

[J10] Y. Ge, M. Wang, M. Li, and T. Wang, “Study of silicon-based optical fiber temperature sensor,” Chinese Journal of Sensors and Actuators, vol. 20, no. 5, pp. 1017-1020, 2007. (In Chinese)

[J9] M. Li, M. Wang, and H. Li, “Optical MEMS pressure sensor based on Fabry-Perot interferometry,” Optics Express, vol. 14, no. 4, pp. 1497-1504, 2006.

[J8] H. Li, M. Li, K. Ogusu, Y. Sheng, and J. E. Rothenberg, “Optimization of a continuous phase-only sampling for high channel-count fiber Bragg gratings,” Optics Express, vol. 14, no. 8, pp. 3152 – 3160, 2006.

[J7] M. Li, M. Wang, H. Rong, and H. Li, “A novel analytical approach for multi-Layer diaphragm-based optical micro-electromechanical-system pressure sensors,” Chinese Physic. Letter, vol. 23, no. 5, pp. 1211-1214, 2006.

[J6] Y. Ge, M. Wang, X. Chen, and M. Li, “A novel Fabry-Perot MEMS fiber pressure sensor based on intensity demodulation method interferometry,” Chinese Journal of Sensors and Actuators, vol. 19, no. 5, pp. 1832-1834, 2006. (In Chinese).

[J5] M. Li, M. Wang, T. Wang, and S. Nie, “Theoretical analysis and numerical simulation of the optical fiber MEMS pressure sensor,” Guangxue Jishu/Optical Technique, vol. 31, no. 4, pp. 491-493, 2005. (In Chinese)

[J4] T. Wang, M. Wang, M. Li, M. Lu, “Dual-wavelength demodulation and wavelength optimization for optical fiber Fabry-Perot sensor,” Guangxue Xuebao/Acta Optica Sinica, vol. 25, no. 10, pp. 1229-1236, 2005. (In Chinese)

[J3] M. Li, M. Wang, T. Wang, and S. Nie, “The design of optical fiber MEMS pressure sensor,” Journal of Nanjing Normal University (Engineering and Technology), vol. 4, no. 4 pp. 21-24, 2004. (In Chinese)

[J2] T. Wang, M. Li, M. Wang, and H. Hao, “The modulation and amplifying circuit design for laser diode self-mixing interference,” Journal of Nanjing Normal University (Engineering and Technology), vol. 4, no. 1 pp.64-66, 2004. (In Chinese)

[J1] M. Wang, S. Nie, M. Li, and D. Li, “Self-mixing interferometry for micro displacement measurement,” Chinese Journal of Scientific Instrument, vol. 25, no. 4, pp. 428, 2004. (In Chinese)

5.个人联系方式（邮箱、电话等）。

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E-mail：ml@semi.ac.cn