宋跃江



宋跃江
副教授
办公室地址:协鑫楼512
办公室电话:025-83597544-512

Email: yjsong@nju.edu.cn



实验室主页:http://ocer.nju.edu.cn

研究方向:
等离子光学微腔理论及应用、光纤非线性激光器、光纤传感、光纤通信等
开设课程
光电子技术、光电仪器原理和实验、光纤非线性光学、导波光学、光纤通信系统等。
个人简介:
宋跃江,南京大学副教授。上海交通大学博士毕业,入选南京大学青年骨干教师培养计划,2013年UC Irvine访问学者。中国光学学会光电专业委员会委员,中国光学学会高级会员,美国光学学会会员。主持国家自然科学基金、博士后基金等基金4项;参与国家自然科学基金重大仪器专项,国家自然科学基金,华为科研基金等多个项目的研究工作。主要研究兴趣包括等离子光学微腔理论及应用、光纤非线性激光器、光纤传感、光纤通信等,已经在PRA, Opt. Lett., Opt. Express等期刊发表论文四十余篇论文,申请/获得发明专利超10项,获教育部技术发明奖一等奖1项(参与)。
科研成果
文章:

1.S. Cai, Y. Xiang, Y. Miao, M. Li, Y. Peng, Y. Song, Mode coupling in metal-coated microsphere,“ Opt Express 24, 013832 (2016).

2.M. Li, B. Li, Y. Song, X. Zhang, L. Chang, and J. Liu, Investigation of costas loop synchronization effect on BER performance of space uplink optical communication system with BPSK scheme, IEEE Photonics Journal 7, 1-9 (2015).

3.M. Li, W. Jiao, X. Liu, Y. Song, and L. Chang, A Method for Peak Seeking of BOTDR Based on the Incomplete Brillouin Spectrum, IEEE Photonics Journal 7, 1-10 (2015).

4.M. Li, W. Jiao, Y. Song, X. Zhang, S. Dong, and Y. Poo, Investigation of the EDFA effect on the BER performance in space uplink optical communication under the atmospheric turbulence, Optics Express 22, 25354-25361 (2014).

5.J. Gu, Z. Zhang, M. Li, and Y. Song, Mode characteristics of metal-coated microcavity, Physical Review A 90, 013816 (2014).

6.C. Yin, J. Gu, M. Li, and Y. Song, Tunable high-Q tapered silica microcylinder filter, Chinese Optics Letters 11, 082302 (2013).

7.J. C. Ding, M. Li, M. H. Tang, Y. Li, and Y. J. Song, The Performance of MSK in Downlink of Ground-to-Satellite Laser Communication Systems, Applied Mechanics and Materials 411, 757-760 (2013).

8.J. Ding, M. Li, M. Tang, Y. Li, and Y. Song, BER performance of MSK in ground-to-satellite uplink optical communication under the influence of atmospheric turbulence and detector noise, Optics Letters 38, 3488-3491 (2013).

9.X. Zhang, R. Wang, Y. Song, J. Wu, and A. K. Sarma, Multi-channel broadband Brillouin slow light with multiple longitudinal mode pump, Journal of Lightwave Technology 30, 49-53 (2012).

10.X. Zhang, Y. Song, and L. Lu, Time Division Multiplexing Optical Time Domain Reflectometry Based on Dual Frequency Probe, IEEE Photonics Technology Letters 24, 2005-2008 (2012).

11.R. Wang, Y. Song, and X. Zhang, Broadband Brillouin slow light with multiple-longitudinal-mode, tunable pump, Chinese Optics Letters 10, 081401 (2012).

12.L. Lv, Y. Song, F. Zhu, and X. Zhang, Performance limit of a multi-frequency probe based coherent optical time domain reflectometry caused by nonlinear effects, Chinese Optics Letters 10, 040604 (2012).

13.L. Lu, Y. Song, F. Zhu, and X. Zhang, Coherent optical time domain reflectometry using three frequency multiplexing probe, Optics and Lasers in Engineering 50, 1735-1739 (2012).

14.L. Lu, Y. Song, F. Zhu, and X. Zhang, Dual frequency probe based coherent optical time domain reflectometry, Optics Communications 285, 2492-2495 (2012).

15.L. Lu, Y. Song, X. Zhang, and F. Zhu, Frequency division multiplexing OTDR with fast signal processing, Optics & Laser Technology 44, 2206-2209 (2012).

16.M. Li, J. Ma, X. Zhang, Y. Song, and W. Du, Investigation of black box model for erbium-doped fiber amplifiers in space radiation environment, Journal of Lightwave Technology 30, 3667-3671 (2012).