Magneto-Optic Fiber Gratings Useful for Dynamic Dispersion Management and Tunable Comb Filtering
WU Bao-Jian, LU Xin, QIU Kun
Key Lab of Broadband Optical Fiber Transmission and Communication Networks of the Ministry of Education, University of Electronic Science and Technology of China, Chengdu 611731
Magneto-Optic Fiber Gratings Useful for Dynamic Dispersion Management and Tunable Comb Filtering
WU Bao-Jian, LU Xin, QIU Kun
Key Lab of Broadband Optical Fiber Transmission and Communication Networks of the Ministry of Education, University of Electronic Science and Technology of China, Chengdu 611731
Intelligent control of dispersion management and tunable comb filtering in optical network applications can be performed by using magneto-optic fiber Bragg gratings (MFBGs). When a nonuniform magnetic field is applied to the MFBG with a constant grating period, the resulting grating response is equivalent to that of a conventional chirped grating. Under a linearly nonuniform magnetic field along the grating, a linear dispersion is achieved in the grating bandgap and the maximal dispersion slope can come to 1260 ps/nm2 for a 10-mm-long fiber grating at 1550 nm window. Similarly, a Gaussian-apodizing sampled MFBG is also useful for magnetically tunable comb filtering, with potential application to clock recovery from return-to-zero optical signals and optical carrier tracking.
Intelligent control of dispersion management and tunable comb filtering in optical network applications can be performed by using magneto-optic fiber Bragg gratings (MFBGs). When a nonuniform magnetic field is applied to the MFBG with a constant grating period, the resulting grating response is equivalent to that of a conventional chirped grating. Under a linearly nonuniform magnetic field along the grating, a linear dispersion is achieved in the grating bandgap and the maximal dispersion slope can come to 1260 ps/nm2 for a 10-mm-long fiber grating at 1550 nm window. Similarly, a Gaussian-apodizing sampled MFBG is also useful for magnetically tunable comb filtering, with potential application to clock recovery from return-to-zero optical signals and optical carrier tracking.
[1] Kaminow I P and Li T Y 2006 Optical Fiber Telecommunication (Beijing: Beijing University of Posts and Telecommunications Press) (in Chinese) [2] Maeda A and Susaki M 2006 IEEE Trans. Magn. 42 3096 [3] Zhang D L, Yang Q Z and Pun B Y E 2008 Chin. Phys. Lett. 25 2904 [4] Chen J X, Wang P and Wang X L et al 2008 Chin. Phys. Lett. 25 4385 [5] Mao T C, Chen J C and Hu C C 2006 J. Cryst. Growth 296 110 [6] Arce-Diego J L, Lopez-Ruisanchez R, Lopez-Higuera J M and Muriel M A 1997 Opt. Lett. 22 603 [7] Yoshino T, Yokota M and Kenmochi T 2003 Electron. Lett. 39 1800 %DOI:10.1049/el:20031130 [8] Ballato J and Snitzer E 1995 Appl. Opt. 34 6848 %DOI:10.1364/AO.34.006848 [9] Sun L, Jiang S and Marciante J R 2010 Optical Fiber Communication Conference (San Diego, CA 21-25 March 2010) p OWL3 [10] Lee B 2003 Opt. Fiber Technol. 9 57 [11] Wu B J, Liu X and Qiu K 2009 Opt. Fiber Technol. 15 165 [12] Qiu K, Wu B J and Wen F 2009 Acta Phys. Sin. 58 1726 (in Chinese) [13] Mora J, Ortega B, Andres M V, Capmany J, Pastor D, Cruz J L and Sales S 2002 Electron. Lett. 38 118 [14] Matyushev V V, Stashkevich A A and Desvignes J M 1991 J. Appl. Phys. 69 5972 [15] Lui X M, Wang L R, Gong Y K, Wang T, Lu K Q, Zhang T Y and Zhao W 2007 Chin. Phys. Lett. 24 1302
2010, Vol. 27 
