Carl E. Lemonds

High performance low power array multiplier using temporal tiling

Digital multipliers are a major source power dissipation in digital signal processors. Array architecture is a popular technique to implement these multipliers due to its regular compact structure. High power dissipation in these structures is mainly due to the switching of a large number of gates during multiplication. In addition, much power is also dissipated due to a large number of spurious transitions on internal nodes. Timing analysis of a full adder, which is a basic building block in array multipliers, has resulted in a different array connection pattern that reduces power dissipation due to the spurious transition activity. Furthermore, this connection pattern also improves the multiplier throughput. This array pattern is based on creating a compact tiled structure, wherein the shape of a tile represents the delay through that tile. That is, a compact structure created using these tiles is nothing but a structure with high throughput. Such a temporal tiling technique can also be applied to other digital circuits. Based on our simulation studies, a temporally tiled array multiplier achieves 50% and 35% improvements in delay and power dissipation compared to a conventional array multiplier. Improvement in delay can be traded for power using voltage reduction techniques.

A multiplexer-based architecture for high-density, low-power gate arrays

This paper presents a novel architecture that provides higher density and lower power dissipation than conventional basecells. The layout of transistors in this small basecell allows the efficient construction of multiplexers with minimal use of programmable layers. The multiplexer can be used to create any 2 input and some 3 input functions in one basecell. Internal fanout, rather than typical output load, defines the size of driver and multiplexer transistors, which can be independently tailored for the desired speed/area/power target. This basecell, which is well suited for implementing datapath elements, has been used to create a 16/spl times/16-b multiplier operating at 50 MHz in 314500 /spl mu/m/sup 2/ in 0.6 /spl mu/m technology. >