Technologies now exist for implementing dense surface-normal optical interconnections for silicon CMOS VLSI using hybrid integration techniques. The critical factors in determining the performance of the resulting photonic chip are the yield on the transceiver device arrays, the sensitivity and power dissipation of the receiver and transmitter circuits, and the total optical power budget available. The use of GaAs--AlGaAs multiple-quantum-well p-i-n diodes for on-chip detection and modulation is one effective means of implementing the optoelectronic transceivers. We discuss a potential roadmap for the scaling of this hybrid optoelectronic VLSI technology as CMOS linewidths shrink and the characteristics of the hybrid optoelectronic tranceiver technology improve. An important general conclusion is that, unlike electrical interconnects, such dense optical interconnections directly to an electronic circuit will likely be able to scale in capacity to match the improved performance of futur...

Reconfigurable computing devices are emerging as a viable alternative to fixed-function components and programmable processors. To expand our knowledge of the role and optimization of these devices, it is increasingly imperative for us to compare implementations of tasks and subroutines across this wide spectrum of implementation options. The fact that most processors, FPGAs, ASICs, and memories are fabricated in a uniform technology medium, CMOS VLSI, where area scaling is moderately well understood eases our comparison task. Nonetheless, the rapid pace of technology, limited device size selection, and economic artifacts complicate the picture. In this paper, we look at the task of comparing computing machines, reviewing normalization techniques and many important issues which arise during comparisons. This paper includes examples intended to underscore the methodology and comparison issues, but does not attempt to make definitive conclusions about the merits of the technology alterna...