Title :
Circuit modeling of quantum-well lasers for optoelectronic integrated circuits (ICs) including physical effect of deep-level traps
Author :
Salehi, Mohammad Reza ; Cabon, Beatrice
Author_Institution :
ENSERG, Grenoble, France
fDate :
11/1/2002 12:00:00 AM
Abstract :
For the purposes of optoelectronic design, this paper presents a new and original small signal two-port circuit model of a quantum-well laser that has been developed from rate equations. This model is based on the physics of the spontaneous emission, stimulated emission, lightwave resonance, high-level injection, active-layer carrier degeneracy, and deep-level traps simultaneously. This model is compatible with general-purpose circuit analysis program (e.g., PSPICE) and is used to determine the frequency modulation bandwidth and the intensity modulation of the semiconductor laser. The results indicate that an increment in the density of the traps causes a decrease in both the amplitude of the output light and the bandwidth of the frequency response and an increase in the steady-state time.
Keywords :
SPICE; deep levels; electro-optical modulation; frequency response; integrated optoelectronics; optical design techniques; quantum well lasers; semiconductor device models; spontaneous emission; stimulated emission; PSPICE; active-layer carrier degeneracy; circuit modeling; deep-level traps; frequency modulation bandwidth; frequency response; high-level injection; intensity modulation; lightwave resonance; optoelectronic design; optoelectronic integrated circuits; physical effect; quantum-well lasers; rate equations; semiconductor laser; small signal two-port circuit model; spontaneous emission; steady-state time; stimulated emission; Bandwidth; Equations; Integrated circuit modeling; Optical design; Physics; Quantum well lasers; Resonance; Signal design; Spontaneous emission; Stimulated emission;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2002.804273
