个人简述：

彭迪，博士，副教授，硕士生导师，广东工业大学“青年百人计划”引进人才。主持国家自然科学基金面上项目、青年项目；参与国家重点研发计划项目、广东省重点领域研发计划项目等。发表SCI/EI学术论文30余篇，获国家发明专利授权10项。主要研究方向为微波光子技术在雷达和无线通信系统中的应用：

（1）基于微波光子技术的雷达和无线通信信号产生，包括宽带微波光子变频技术、高性能光电振荡器等。

（2）微波光子信号处理技术，包括基于光学时间拉伸的模数转换技术、基于色散傅里叶变换的宽带测频技术、基于分数阶傅里叶变换的啁啾信号测量技术等。

（3）微波光子信号传输技术，包括光载无线信号的远距离馈送、光纤信能共传技术等。

学科领域：

科学学位：信息与通信工程（0810）

专业学位：信息与通信工程（0810）

教育背景：

2011-09至2017-12，电子科技大学，光电信息学院，博士

2007-09至2011-06，电子科技大学，光电信息学院，学士

工作经历：

2020/07-至今，广东工业大学，信息工程学院，讲师，副教授

2018/03-2020/06，广东工业大学，机电工程学院，讲师

主要论文：

(34) M. X. Yuan, D. Peng*, S. N. Fu, J. P. Li, M. Xiang, Y. W. Qin*, Multi-band radar based on a cavity-less ultra-short optical pulse source for simultaneous measurement of distance and velocity, Journal of Lightwave Technology, 2024

(33) M. X. Yuan, D. Peng*, Y. W. Qin*, J. P. Li, M. Xiang, O. Xu, S. N. Fu, Broadband microwave photonic mixer with flexibly tunable phase shift and supporting dispersion-induced power-fading-free fiber transmission, Photonics, 2023, 10(4): 432

(32) L. Z. Xu, D. Peng*, Y. W. Qin*, J. P. Li, M. Xiang, O. Xu, S. N. Fu, Image-rejected multi-band frequency down-conversion based on photonic sampling, Photonics, 2023, 10(1): 35

(31) J. Ou, J. P. Li*, W. Q. Zheng, Y. W. Qin, N. Lin, O. Xu, Q. D. Huang, D. Peng, M. Xiang, Y. Xu, S. N. Fu, Design and analysis of weakly coupled few-mode hollow-core U-shaped tube nested antiresonant fiber, Journal of the Optical Society of America B, 2023, 40(5): 1170-1181

(30) L. J. Liu, D. Peng*, S. N. Fu, Y. C. Wang, Y. W. Qin, Multi-band microwave signals generation based on a photonic sampling with a flexible ultra-short pulse source, Optics Express, 2022, 30(18): 32151-32161

(29) D. Peng, H. Q. Li, Y. W. Qin*, J. P. Li, S. N. Fu, Robust wide-range chirp rate measurement based on a flexible photonic fractional Fourier transformer, Optics Express, 2022, 30(5): 7750-7762 (28) M. X. Yuan, D. Peng*, Y. W. Qin*, J. P. Li, M. Xiang, O. Xu, S. N. Fu, Broadband multi-frequency microwave photonic up-conversion with tunable phase shift, Optics Communications, 2022,520(9): 128518

(27) Y. C. Su, Z. Zeng, D. Peng, J. Min, L. J. Zhang, Y. L. Zhang*, Z. Y. Zhang, S. J. Zhang, H. P. Li, Y. Liu, Injection-locked optoelectronic oscillator with high side-mode suppression ratio and low phase noise based on frequency-conversion delay matching, Optics and Laser Technology, 2022, 156: 108462

(26) W. C. Yuan, Z. W. Fu, Y. L. Wu, D. Peng, L. J. Zhang, Z. Zeng, Y. L. Zhang*, Z. Y. Zhang, S. J. Zhang, Y. Liu, Time-domain convolution model for studying oscillation dynamics in an injection-locked optoelectronic oscillator, Optics Express, 2022, 30(22): 40728-40738

(25) H. L. Yang, S. Wang, D. Peng, Y. W. Qin*, S. N. Fu, Optically powered 5G WDM fronthaul network with weakly-coupled multicore fiber, Optics Express, 2022, 30(11), 19795-19804

(24) S. Wang, H. L. Yang, Y. W. Qin*, D. Peng, S. N. Fu, Power-over-fiber in support of 5G NR fronthaul: space division multiplexing versus wavelength division multiplexing, Journal of Lightwave Technology, 2022, 40(13), 4169-4177

(23) M. Xiang, S. N. Fu, O. Xu, J. P. Li, D. Peng, Z. S. Gao, Y. C. Wang, Y. W. Qin*, Advanced DSP enabled C-band 112 Gbit/s/λ PAM-4 transmissions with severe bandwidth-constraint, Journal of Lightwave Technology, 2022, 40(4), 987-996

(22) Q. D. Huang, X. B. Wang, J. L. Dong, Z. Q. Zheng, O. Xu, S. N. Fu, D. Peng, J. P. Li, Y. W. Qin, Ultra-broadband LP11 mode converter with high purity based on long-period fiber grating and integrated Y-junction, Optics Express, 2022, 30(8): 12751-12759

(21) H. L. Yang, D. Peng*, Y. W. Qin*, J. P. Li, M. Xiang, O. Xu, S. N. Fu, 10-W power light co-transmission with optically carried 5G NR signal over standard single-mode fiber, Optics Letters, 2021, 46(20): 5116-5119

(20) Y. W. Zhang, R. T. Jin, D. Peng*, W. Q. Lyu, Z. W. Fu, Z. Y. Zhang*, S. J. Zhang, H. P. Li, Y. Liu, Broadband transient waveform digitizer based on photonic time stretch, Journal of Lightwave Technology, 2021, 39(9): 2880-2887

(19) 杨海林, 刘丽娟, 彭迪, 许鸥, 秦玉文*. 光纤信能共传技术研究进展, 光学学报, 2021, 41(11): 1100001

(18) M. Xiang, L. Hong, S. N. Fu, J. P. Li, O. Xu, D. Peng, Z. S. Gao, Y. C. Wang, Y. W. Qin, Hardware-efficient blind frequency offset estimation for digital subcarrier multiplexing signals, Optics Express, 2021, 29(13): 4246 - 4256

(17) S. N. Fu, M. Xiang, P. J. Zhou, B. L. Ye, O. Xu, J. P. Li, D. Peng, Y. C. Wang, Y. W. Qin, Adaptive intensity transformation based phase-retrieval with high accuracy and fast convergence, Optics Letters, 2021, 46(13): 3215-3218

(16) W. Q. Zheng, Y. W. Qin, O. Xu, M. Xiang, D. Peng, S. N. Fu, J. P. Li, Wideband low confinement loss anti-resonant hollow core fiber with nested U-shaped tube, Optics Express, 2021, 29(15): 24182-24192

(15) D. Peng, H. M. Jiang, F. C. Shen, H. Y. Xia, K. Xie*, Reconfigurable high-resolution photonic fractional Fourier transformer for broadband frequency measurement and large-scale chirp rate characterization of microwave signals, Optics Communications, 2020, 460: 125157

(14) X. Y. Zhang, D. Peng*, Y. X. Ma, B. T. Wang, M. K. Wang, Z. K. Li, Z. Y. Zhang, S. J. Zhang, H. P. Li, Y. Liu. Broadband high-resolution microwave frequency measurement based on photonic undersampling via using three cavity-less optical pulse sources with coprime repetition rates, Applied Optics, 2020, 59(27): 8056-8065

(13) Z. Zeng, D. Peng, Z. Y. Zhang, S. J. Zhang, G. M. Ni*, Y. Liu, An SBS-based optoelectronic oscillator for high-speed and high-sensitivity temperature sensing, IEEE Photonics Technology Letters, 2020, 32(16): 995-998

(12) F. C. Shen, K. M. Zhou, C. L. Wang, H. M. Jiang, D. Peng, H. Y. Xia, K. Xie, L. Zhang, Polarization dependent cladding modes coupling and spectral analyses of excessively tilted fiber grating. Optics Express, 2020, 28(2): 1076-1083

(11) R. T. Jin, Y. W. Zhang, D. Peng, Z. Y. Zhang, S. J. Zhang, H. P. Li, Y. Liu. Photonic time-stretch analog-to-digital conversion based on complementary parallel single-sideband modulation architecture, International Conference on Optoelectronic and Microelectronic Technology and Application, Nanjing, P. R. China, 2020.10.20-10.22

(10) D. Peng, Z. Y. Zhang*, Z. Zeng, L. J. Zhang, Y. J. Lyu, Y. Liu, K. Xie*, Single-shot photonic time-stretch digitizer using a dissipative soliton-based passively mode-locked fiber laser, Optics Express, 2018, 26(6): 6519-6531

(9) D. Peng, Z. Y. Zhang*, Y. X. Ma, Y. L. Zhang, S. J. Zhang, Y. Liu, Optimized single-shot photonic time-stretch digitizer using complementary parallel single-sideband modulation architecture and digital signal processing, IEEE Photonics Journal, 2017, 9(3): 5501514

(8) Y. X. Ma, D. Liang, D. Peng, Z. Y. Zhang*, Y. L. Zhang, S. J. Zhang, Y. Liu, Broadband high-resolution microwave frequency measurement based on low-speed photonic analog-to-digital converters. Optics Express, 2017, 25(3): 2355-2368

(7) M. K. Shah, R. G. Lu, D. Peng, Y. X. Ma, S. W. Ye, Y. L. Zhang, Z. Y. Zhang, Y. Liu, Graphene-assisted polarization-insensitive electro-absorption optical modulator. IEEE Transactions on Nanotechnology, 2017, 16(6):1004-1010

(6) S. B. Wang, Z. Y. Zhang, D. Peng, X. Y. Zhang, Y. Liu*, Sagnac-loop-based optical coding for all-optical analog-to-digital conversion employing soliton self-frequency shift. Acta Photonica Sinica, 2017, 46(11): 1125002

(5) D. Peng, Z. Y. Zhang*, Y. X. Ma, Y. L. Zhang, S. J. Zhang, Y. Liu, Broadband linearization in photonic time-stretch analog-to-digital converters employing an asymmetrical dual-parallel Mach-Zehnder modulator and a balanced detector, Optics Express, 2016, 24(11): 11546-11557

(4) D. Peng, Z. Y. Zhang*, Y. X. Ma, Y. L. Zhang, S. J. Zhang, Y. Liu, Broadband linearization in photonic time-stretch analog-to-digital converters, 25th Wireless and Optical Communication Conference, Chengdu, P.R. China, 2016.5.21-5.23

(3) Y. X. Ma, Z. Y. Zhang*, D. Peng, J. F. Zou, Y. Liu, Microwave frequency measurement based on photonic sampling analog-to-digital conversion. SPIE/COS Photonics Asia, International Society for Optics and Photonics, Beijing, P.R. China, 2016.10.12-10.14

(2) S. W. Peng, Z. Y. Zhang*, Q. H. Yang, D. Peng, Y. L. Zhang, Y. Liu, Gain fluctuation in microwave photonics phase shifters based on stimulated Brillouin scattering. 25th Wireless and Optical Communication Conference, Chengdu, P.R. China, 2016.5.21-5.23

(1) D. Peng, Z. Y. Zhang, F. Yang, F. Yuan, Y. Liu*, Demonstration of a 10-fold stretch-factor photonic analog-to-digital converter for a 5 GHz radio-frequency signal, Acta Photonica Sinica, 2014, 43(7): 0706015

 

知识产权（授权发明专利）：

(10)彭迪,袁明秀,付松年,李建平，向梦，许鸥，秦玉文;一种相位可调的微波光子变频系统及其实现方法,2023-07-25,中国,ZL202110622882.5

(9)彭迪,许留柱,付松年,李建平,向梦,许鸥,秦玉文;一种基于光频梳的多频段微波光子变频系统,2022-6-17,中国,ZL202110985547.1

(8)彭迪,刘丽娟,杨海林,高震森,李建平,许鸥,秦玉文;一种基于非线性光学传输线的微波上变频器及其实现方法,2022-9-23,中国, ZL202010834686.X

(7)秦玉文,刘丽娟,彭迪,杨海林,付松年,李建平,向梦,许鸥;一种光纤能量信息共传系统的安全监测方法及装置,2022-6-21,中国,ZL202110986061.X

(6)彭迪,谢康,姜海明,申方成,夏宏燕;一种宽带可调谐高精度光学分数阶傅里叶变换器及其实现方法,2020-10-16,中国,ZL201910443960.8

(5)王舒冰,彭迪,张旨遥,张戌艳,李和平,刘永;一种用于孤子自频移全光模数转换的编码装置及方法,2019-12-6,中国,ZL201710138740.5.

(4)张旨遥,马阳雪,杨帆,彭迪;一种基于光学模数转换的微波信号测频方法及装置,2019-2-5,中国,ZL201610272724.0.

(3)彭迪,张旨遥,马阳雪,李和平,张尚剑,张雅丽,刘永;一种基于时间拉伸的微波信号光学模数转换方法及装置,2018-3-2,中国,ZL201610038778.0.

(2)彭迪,张旨遥,马阳雪,徐亚然,杨帆,刘永;一种用于光学时间拉伸模数转换的相位补偿方法,2018-3-23,中国,ZL201610326812.4.

(1)刘永,叶胜威,邹新海,彭迪,吴雨祥,张雅丽,陆荣国;针对光通信系统模拟软件中的光调制器频率响应的方法,2017-2-22,中国,ZL201410558201.3.

科研项目：

1、2022-01至2025-12，主持国家自然科学基金面上项目， 62175038，基于变频滤波光电振荡器的B5G基站毫米波信号产生研究，60万元。

2、2019-01至2021-12，主持国家自然科学基金青年项目，61805046，可调谐高精度光学分数阶傅里叶变换器基础研究，25万元。

3、2019-07至2023-06，作为项目骨干，参与国家重点研发计划“宽带通信和新型网络”重点专项，2018YFB1801000，基于新波段、新光纤、新放大的高速光传输技术及系统验证，2799万元。

4、2019-01至2021-12，作为项目的技术负责人和实施者，参与广东省重点领域研发计划项目，2018B010114002，光子-无线融合的分布式5G系统关键技术，702万元（总经费3000万元）。

5、2016-01至2019-12，作为项目骨干，参与国家自然科学基金面上项目，61575037，基于拉曼自频移效应的高速高精度全光模数转换技术基础研究， 75.24万元。

6、2015-08至2017-07，作为主要研究者，参与 “微波信号光学模数转换器” 项目(中电24所中电协同创新项目)，负责高速高精度模数转换样机的研制，项目经费：300万元。

7、2014-07至2016-06，作为主要研究者，参与“XXXXX模数转换技术”，负责高速高精度光学模数转换器的方案设计及相关关键技术研究，项目经费：70万元。

8、2012-01至2015-12，作为主要研究者，参与“XXXXXX模数转换器研究”项目，负责光学时间拉伸模数转换原理样机的研制，项目经费：250万元。

9、2017-01至2020-12，作为主研人员，参与“基于微波光子学的XXXXX信号发生与数字采集技术”，负责宽带高速光学时间拉伸实时示波器的研制，项目经费：285万元。

教学活动：

承担本科生课程《光电检测技术》《安全检测与控制技术》

承担研究生课程《微波光子学》

我的团队：

隶属于先进光子技术研究院，团队专注于光纤通信、光纤传感、保密通信等方面的研究工作。