In this paper, a steady-state model for ridge waveguide DFB lasers is presented. The complex two-dimensional semivectorial optical mode in the transverse direction is solved using a finite difference scheme without introducing any approximations. The electron and hole diffusion in the lateral direction is also considered, Along the longitudinal direction, a novel "Superposition of Spectral Power Method" is used, based on the coupled mode formulation. This model enables one to examine the interaction between the optical and carrier profiles for different injection levels and arbitrary transverse index profiles. As such, it is useful for studying CW characteristics such as lasing wavelength and threshold current. Finally, the results from this model are compared with experimental data from a varying ridge width laser array fabricated from a 1.55 /spl mu/m InGaAsP-InP compressively strained multiquantum-well loss-coupled DFB structure.
[1]
Wei-Ping Huang,et al.
A two-dimensional DFB laser model accounting for carrier transport effects
,
1995
.
[2]
W. Huang,et al.
Static and dynamic simulation for ridge-waveguide MQW DFB lasers
,
1995
.
[3]
T. Detemple,et al.
On the semiconductor laser logarithmic gain-current density relation
,
1993
.
[4]
T. Makino,et al.
Multi-/spl lambda/ ridge waveguide gain-coupled DFB laser array
,
1995
.
[5]
Geert Morthier,et al.
CLADISS-a longitudinal multimode model for the analysis of the static, dynamic, and stochastic behavior of diode lasers with distributed feedback
,
1990
.
[6]
J. Carroll,et al.
Large-signal dynamic model of the DFB laser
,
1992
.