Reliable Low-Power Multiplier Design Using Fixed-Width Replica Redundancy Block

Author

I-Chyn Wey ; Chien-Chang Peng ; Feng-Yu Liao

Author_Institution

Electr. Eng. Dept., Chang Gung Univ., Taoyuan, Taiwan

Volume

23

Issue

1

fYear

2015

fDate

Jan. 2015

Firstpage

78

Lastpage

87

Abstract

In this paper, we propose a reliable low-power multiplier design by adopting algorithmic noise tolerant (ANT) architecture with the fixed-width multiplier to build the reduced precision replica redundancy block (RPR). The proposed ANT architecture can meet the demand of high precision, low power consumption, and area efficiency. We design the fixed-width RPR with error compensation circuit via analyzing of probability and statistics. Using the partial product terms of input correction vector and minor input correction vector to lower the truncation errors, the hardware complexity of error compensation circuit can be simplified. In a 12×12 bit ANT multiplier, circuit area in our fixed-width RPR can be lowered by 44.55% and power consumption in our ANT design can be saved by 23% as compared with the state-of-art ANT design.

Keywords

digital signal processing chips; error compensation; error correction; low-power electronics; redundancy; ANT architecture; RPR; algorithmic noise tolerant architecture; error compensation circuit; fixed-width multiplier; fixed-width replica redundancy block; reduced precision replica redundancy block; reliable low-power multiplier design; Computer architecture; Delays; Error compensation; Finite wordlength effects; Logic gates; Power demand; Vectors; Algorithmic noise tolerant (ANT); fixed-width multiplier; reduced-precision replica (RPR); voltage overscaling (VOS); voltage overscaling (VOS).;

fLanguage

English

Journal_Title

Very Large Scale Integration (VLSI) Systems, IEEE Transactions on

Publisher

ieee

ISSN

1063-8210

Type

jour

DOI

10.1109/TVLSI.2014.2303487

Filename

6740009