[1] Nvkolak G et al.Systems evaluation of an Er3+-doped planar waveguide amplifier [J].IEEE Photonics Technol.Lett.,1993,5(10): 1185～1187

[2] Shooshtari A et al.Yb3+ sensitized Er3+-doped waveguide amplifiers: a theoretical approach [C].SPIE..1998,3278:149～165

[3] Choi Y B,Cho S H.Er-Al codoped silicate planar light waveguide-type amplifier fabricated by radio-frequency sputtering [J].Optics.Lett.,2000,25(4): 263～265

[4] Fabrizio Di Pasquale,Maurizio Zoboli.Analysis of erbium-doped waveguide amplifiers by a full-vectorial finiteelement method [J].IEEE J.Lightwave Technol,1993,11(10): 1565～1573

[5] Federico Caccavale et al.A numerical study of erbium doped active LiNbO3 waveguides by the beam propagation method [J].IEEE J.Lightwave Technol,1997,15(12): 2294～2299

[6] Vermelho M V D et al.Simple and accurate procedure for modeling erbium-doped waveguide amplifiers with high concentration [J].IEEE J.Lightwave Technol,2000,18(3): 401～407

[7] Giles C R,Desurvire E.Modeling erbium-doped fiber amplifiers [J].J.Lightwave Technol,1991,9(3): 271～283

[8] Rebolledo M A.Jarabo S.Erbium-doped silica fiber modeling with overlapping factors [J].Appl.Opt.,1994,33(18):5585～5593

[9] Snoeks E.Kik P G,Polman A.Concentration quenching in erbium-implanted alkali-silica glasses [J].Opt.Mater.,1996.5(1): 159～167