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提出并验证了一种有源环形谐振腔辅助滤波的光电振荡器. 它利用有源环形谐振腔提供的高Q光学梳状频率响应特性, 对振荡器中的光信号模式进行选择, 能有效地提高输出信号的边模抑制比, 获得光电振荡器的单模输出. 理论上, 对光电振荡器的起振模式以及有源腔的频率响应进行了分析, 仿真结果表明有源环形谐振腔的辅助滤波有利于光电振荡器的边模抑制和单模输出. 在实验上, 通过对比验证了理论的预期结果, 并最终得到中心频率为20 GHz, 边模抑制比为58.83 dB, 在频偏10 kHz处相位噪声为-97 dBc/Hz的单模信号输出. 该方案保留了已有光电振荡器边模抑制方法的优势, 实现方法上更加简便, 在工作带宽和可调谐性方面具备良好的灵活性.In this paper, a single mode optoelectronic oscillator assisted by active ring resonance cavity filtering is presented and verified. Using the high Q optical comb frequency response to select the oscillation mode of an optoelectronic oscillator, the system can effectively suppress the side-mode and generate single mode signal. Theoretically, the optoelectronic oscillator oscillation mode and the frequency response of the active cavity are analyzed. The simulation results show that the active ring resonance cavity filtering is of benefit to the side-mode suppression and single mode output in an optoelectronic oscillator system. By comparing with experimental result, the theoretical prediction is verified. The output of a 20 GHz single-mode signal with a side-mode suppression ratio of 58.83 dB and a phase noise of -97 dBc/Hz at 10 kHz from carrier is also obtained. This scheme has the advantages of the existing optoelectronic oscillator side-mode suppression methods. In addition, it has more convenient manipulation, and good flexibility and tunability.
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Keywords:
- optical fiber communication /
- optoelectronic oscillator /
- active resonance cavity /
- side-mode suppressing
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[19] Ma L, Zhu H L, Liang S, Zhao L J, Chen M H 2013 Chin. Phys. B 22 054211
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[1] Yao J P 2009 J. Lightwave Technol. 27 314
[2] Smith S D, Neale R F 1993 Optical Information Technology (Edinburgh: Springer) p328
[3] Sun B, Yu J L, Wang J, Miao W, Meng T H, Wang W R, Yang E Z 2012 Chin. J. Lasers. 39 0305010 (in Chinese) [孙斌, 于晋龙, 王菊, 苗旺, 孟天晖, 王文睿, 杨恩泽 2012 中国激光 39 0305010]
[4] Yao X S, Maleki L 1996 J. Opt. Soc. Am. B 13 1725
[5] Yao X S, Maleki L 1994 Electron. Lett. 30 1525
[6] Yao X S, Maleki L 1996 Opt. Lett. 21 483
[7] Li K, Wang A B, Zhao T, Wang Y C 2013 Acta Phys. Sin. 62 144207 (in Chinese) [李凯, 王安帮, 赵彤, 王云才 2013 62 144207]
[8] Jiang Y, Bai G F, Li H W, Zhou Z Y, Xu J, Wang S Y 2013 IEEE Photon. Technol. Lett. 25 382
[9] Jiang Y, Yu J L, Hu L, Zhang L 2008 Laser Optoelectron. Prog. 10 39 (in Chinese) [江阳, 于晋龙, 胡林, 张莉 2008 激光与光电子学进展 10 39]
[10] Djordjev K, Choi S J, Choi S J, Dapkus P D 2002 IEEE Photon. Technol. Lett. 14 828
[11] Chen J X, Chen S Y, Shi Y, Yan B, Xu J X 2013 Acta Opt. Sin. 33 0706016 (in Chinese) [陈吉欣, 陈少勇, 师勇, 鄢勃, 徐嘉鑫 2013 光学学报 33 0706016]
[12] Yao X S, Maleki L 2000 J. Quant. Electron. 36 79
[13] Zhou W M, Blasche G 2005 IEEE Trans. Microw. Theory Tech. 53 929
[14] Jiang Y, Yu J L, Wang Y T, Zhang L T, Yang E Z 2007 IEEE Photon. Technol. Lett. 19 807
[15] Eliyahu D, Sariri K, Taylor J, Maleki L 2003 Proceedings of SPIE San Jose, USA, January 25, 2003 p139
[16] Liu M T, Yang A Y, Sun Y N 2009 Acta Phys. Sin. 58 980 (in Chinese) [刘茂桐, 杨爱英, 孙雨南 2009 58 980]
[17] Zhang X L, Sun J Q, Liu D M, Huang D X 2000 Acta Phys. Sin. 49 741 (in Chinese) [张新亮, 孙军强, 刘德明, 黄德修 2000 49 741]
[18] Dong J J, Luo B W, Huang D X, Zhang X L 2012 Chin. Phys. B 21 043201
[19] Ma L, Zhu H L, Liang S, Zhao L J, Chen M H 2013 Chin. Phys. B 22 054211
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