Title :
Phase-locked arrays of antiguides: analytical theory II
Author :
Botez, Dan ; Napartovich, Anatolii P. ; Zmudzinski, Charles A.
Author_Institution :
Dept. of Electr. Eng., Wisconsin Univ., Madison, WI, USA
fDate :
2/1/1995 12:00:00 AM
Abstract :
By employing a variational technique on the eigenvalue equation for finite arrays of antiguides we obtain accurate analytical expressions for key parameters characterizing the adjacent array modes: the edge radiation loss, the loss caused by interelement losses, and the effective index. The upper adjacent mode at its maximum-loss point is found to be well approximated by the sum of two Bloch waves of wavenumbers ±π/[(N-1)Λ], where N is the element number, and Λ is the array period. The intermodal discrimination, Δα, between the adjacent mode and the resonant mode (at the adjacent-mode maximum-loss point) is found to be well approximated (<10% error) by αRR, the resonant-mode loss at resonance. Accurate analytical expressions are also derived for the two-dimensional optical-mode confinement factor Γ, and the dispersion between the resonant and adjacent modes. The obtained analytical formulas are discussed in light of device design, and general design rules are presented
Keywords :
laser mode locking; laser modes; laser theory; optical design techniques; optical losses; semiconductor laser arrays; variational techniques; Bloch waves; adjacent array modes; analytical expressions; analytical theory; antiguides; design rules; dispersion; edge radiation loss; effective index; eigenvalue equation; interelement losses; intermodal discrimination; laser diode arrays; maximum-loss point; phase-locked arrays; two-dimensional optical-mode confinement factor; variational technique; wavenumbers; Apertures; Cause effect analysis; Laser beams; Optical arrays; Optical losses; Optical refraction; Optical resonators; Phased arrays; Power generation; Resonance;
Journal_Title :
Quantum Electronics, IEEE Journal of
