Title
Majority-Based Spin-Cmos Primitives For Approximate Computing
Keywords
accuracy-configurable adder; Approximate computing; compressor; domain wall motion device; spintronic
Abstract
Promising for digital signal processing applications, approximate computing has been extensively considered to tradeoff limited accuracy for improvements in other circuit metrics such as area, power, and performance. In this paper, approximate arithmetic circuits are proposed by using emerging nanoscale spintronic devices. Leveraging the intrinsic current-mode thresholding operation of spintronic devices, we initially present a hybrid spin-CMOS majority gate design based on a composite spintronic device structure consisting of a magnetic domain wall motion stripe and a magnetic tunnel junction. We further propose a compact and energy-efficient accuracy-configurable adder design based on the majority gate. Unlike most previous approximate circuit designs that hardwire a constant degree of approximation, this design is adaptive to the inherent resilience in various applications to different degrees of accuracy. Subsequently, we propose two new approximate compressors for utilization in fast multiplier designs. The device-circuit SPICE simulation shows 34.58% and 66% improvement in power consumption, respectively, for the accurate and approximate modes of the accuracy-configurable adder, compared to the recently reported domain wall motion-based full adder design. In addition, the proposed accuracy-configurable adder and approximate compressors can be efficiently utilized in the discrete cosine transform (DCT) as a widely-used digital image processing algorithm. The results indicate that the DCT and inverse DCT (IDCT) using the approximate multiplier achieve ∼2x energy saving and 3x speed-up compared to an exactly-designed circuit, while achieving comparable quality in its output result.
Publication Date
7-1-2018
Publication Title
IEEE Transactions on Nanotechnology
Volume
17
Issue
4
Number of Pages
795-806
Document Type
Article
Personal Identifier
scopus
DOI Link
https://doi.org/10.1109/TNANO.2018.2836918
Copyright Status
Unknown
Socpus ID
85047010342 (Scopus)
Source API URL
https://api.elsevier.com/content/abstract/scopus_id/85047010342
STARS Citation
Angizi, Shaahin; Jiang, Honglan; DeMara, Ronald F.; Han, Jie; and Fan, Deliang, "Majority-Based Spin-Cmos Primitives For Approximate Computing" (2018). Scopus Export 2015-2019. 10335.
https://stars.library.ucf.edu/scopus2015/10335