[1] [1] Meltz G, Morey W W, Glenn W H. Formation of Bragg gratings in optical fibers by a transverse holographic method. Opt. Lett., 1989, 14(15):823～825

[2] [2] Ball G A, Morey W W. Compression-tuned single-frequency Bragg grating fiber laser. Opt. Lett., 1994, 19(23):1979～1981

[3] [3] Liaw S K,Lee C C, Ho K P et al.. Power equalized wavelength-selective fiber lasers using fiber Bragg gratings. Opt. Commum., 1998, 155(4～6):255～259

[4] [4] Ibsen M, Alam S U, Zervas A N et al.. 8- and 16-channel all-fiber DFB laser WDM transmitters with integrated pump redundancy. IEEE Photonic Technol., 1999, 11(9):1114～1116

[5] [5] Yun S H, Richardson D J, Kim B Y. Interrogation of fiber grating sensor arrays with a wavelength-swept fiber laser. Opt. Lett., 1998, 23(11):843～845

[6] [6] Pask H M, Carman R J, Hanna D C et al.. Ytterbium-doped silica fiber lasers: Versatile sources for the 1～1.2 μm region. IEEE J. Sel. Top Quant., 1995, 1(1):2～13

[7] [7] Hill K O, Meltz G. Fiber Bragg grating technology fundamentals and overview. J. Lightwave Technol., 1997, 15(8):1263～1276

[8] [8] Chernikov S V, Taylor J R. Coupled-cavity erbium fiber lasers incorporating fiber grating reflectors. Opt. Lett., 1993, 18(23):2023～2025

[9] [9] Xu Y Z, Tam H Y, Liu S Y et al.. Pump-induced thermal effects in Er-Yb fiber grating DBR lasers. IEEE Photonic Technol., 1998, 10(9):1253～1255

[10] [10] Man W S, Xu Y Z, Tam H Y et al.. Frequency instability in Er/Yb fiber grating lasers due to heating by nonradiative transitions. IEEE Photonic Technol., 1999, 11(11):1390～1392