1 Gb/s VCSEL/CMOS flip-chip 2-D-array interconnects and associated diffractive optics

980-nm substrate-emitting oxidized-aperture VCSELs with threshold currents in the 150 /spl mu/A to 500 /spl mu/A range have been developed for optoelectronic interconnects. 8/spl times/8 VCSEL arrays with 125 /spl mu/m pitch have been flip-chip bonded to CMOS driver circuitry having 0.5 /spl mu/m gate size. InGaAs/InP 8/spl times/8 detector arrays have been flip-chip bonded to provide good responsivity and high speed detection in dense arrays with 125 /spl mu/m pitch. Data rates as high as 1.1 Gb/s have been demonstrated with the incorporation of refractive coupling optics between transmitter and receiver arrays. Studies have been conducted of crosstalk and alignment sensitivity of these optoelectronic interconnect arrays. Design and modeling techniques have been demonstrated for the development of diffractive optics for optoelectronic interconnects. Special techniques have been developed to deal with very short working distances and subwavelength feature in the diffractive optics. Fan-out performance up to 7/spl times/7 with accurately controlled intensity weights has been demonstrated with diffractive optics. The use of diffractive optics in optoelectronic interconnects with fan-out and/or fan-in can make the interconnect an integral part of the optoelectronic processing algorithm.

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