Low-power digit-serial multipliers

Abstract

Digit-serial implementation styles are best suited for implementation of digital signal processing systems which require moderate sampling rates. Digit-serial multipliers obtained using traditional unfolding techniques cannot be pipelined beyond a certain level because of the presence of feedback loops. In this paper, an alternative approach for the design of digit-serial multipliers is presented based on a novel cell replacement transformation. This transformation permits bit-level pipelining of the digit-serial multipliers thereby achieving sample speeds close to corresponding bit-parallel multipliers with significantly lower area. This increased sample speed can be traded with reduction in power supply voltage resulting in significant reduction in power consumption. The results show that for smaller digit-sizes (/spl les/4), the type-II multiplier consumes the least power and for larger digit-sizes, the type-I multiplier consumes the least power. It is also found that the optimum digit-size for least power consumption in type-I and type-III multipliers is /spl sim//spl radic/2W, where W represents the word length. The proposed digit-serial multipliers consume on an average 1.75 times lower power than the traditional digit-serial architectures for the non-pipelined case, and about 15 times lower power for the bit-level pipelined case.