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Design and analysis of low power 8-bit ALU on reversible logic for nanoprocessors

  • T. M. Amirthalakshmi
  • S. Selvakumar Raja
Original Research
  • 14 Downloads

Abstract

A low power reversible 8-bit ALU using single electron transistor (SET) for Nano processors is designed in this paper. Since there is a possibility in reversible logic to build circuits from many-port gates that do not destroy the capacity to store information, the basic blocks of ALU are constructed using one of the assuring many port gates called DKGP reversible gate. Then the blocks are technologically advanced to the transistor level using CMOS technology. The outputs are verified for given input frequency with the operating voltage of 5 V using SPICE simulation. It is also observed that the output glitches are obtained with low operating voltage of less than 2 V in CMOS technology. The same blocks of ALU are constructed using SET technology and the outputs are verified through simulation. The simulation results have shown that the same output response with no glitches is obtained for the same input frequency as in CMOS, with very low operating voltage of 25 mV. It is inferred that there is a drastic difference in power dissipation with SET and CMOS technology. Therefore SET technology has the potential toward the development of Nano-electronic components and can be adopted for various low power digital applications. This is the first attempt to design reversible ALU using pure SET technology from our study.

Keywords

ALU CMOS Reversible logic Single electron transistor 

Notes

References

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Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2018

Authors and Affiliations

  1. 1.Department of Electronics and Communication EngineeringSathyabama UniversityChennaiIndia
  2. 2.Kakatiya Institute of Technology and ScienceNizamabadIndia

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