Title :
Creation and optimization of vertical-cavity X-modulators
Author :
Trezza, John Alfred ; Morf, M. ; Harris, J.S., Jr.
Author_Institution :
Stanford Univ., CA, USA
fDate :
1/1/1996 12:00:00 AM
Abstract :
We have developed a photon conserving, reversible optoelectronic intensity modulator. The device works by using quantum wells in a slightly asymmetric InGaAs-AlGaAs QW Fabry-Perot cavity to direct an incident optical beam to transmit through the device or to be reflected from the device depending upon the state of the switching element. The first experimental device simultaneously switches reflectivity and transmission from 6% to 60% and 60% to 6%, respectively. We also examine the cavity design parameter space and effects of incident angle on device performance. Furthermore, experimental results from combinations of stacked devices are discussed. A theoretical analysis of the X-modulator design parameter space is given as is an analysis of the system response of our two element stacked devices. Finally, a thorough theoretical treatment of crossbar switches using symmetric X-modulators is provided
Keywords :
Fabry-Perot resonators; III-V semiconductors; aluminium compounds; electro-optical modulation; electro-optical switches; gallium arsenide; indium compounds; optical design techniques; optimisation; reflectivity; semiconductor quantum wells; symmetry; InGaAs-AlGaAs; X-modulator design parameter space; cavity design parameter space; crossbar switches; device performance; element stacked devices; incident angle; incident optical beam; photon conserving; quantum wells; reflectivity; reversible optoelectronic intensity modulator; simultaneously switches; slightly asymmetric InGaAs-AlGaAs QW Fabry-Perot cavity; stacked devices; switching element; symmetric X-modulators; system response; transmission; vertical-cavity X-modulator optimisation; Absorption; Amplitude modulation; Intensity modulation; Optical attenuators; Optical beams; Optical devices; Optical losses; Optical modulation; Optical switches; Phase modulation;
Journal_Title :
Quantum Electronics, IEEE Journal of
