Reversible logic-based magnitude comparator (RMC) circuit using modified-GDI technique for motion detection applications in image processing.

Reversible or information lossless gates have applications in nano-technology, digital signal processing (DSP), communication, computer graphics and cryptography. Gate-diffusion input (GDI) technique can provide the possibility of designing fundamental gates in ultra-low power and layout chip area with low number of transistors. A reversible logic-based single-bit magnitude comparator (RMC) circuit is presented by using the modified-GDI (m-GDI) method-based reversible gates for designing RMC in any arbitrary number of bit levels for processing at nano-scales. In this paper, several figure of merits (FOMs) like: energy consumption-propagation delay product (EDP) and worst delay-power consumption-chip area product (DPA) are evaluated and compared with other designs. The simulation results show the improvement of the evaluation parameters of the proposed RMC in compare with the other similar basic GDI-based comparators. Also, according to the simulation results, presented comparator is capable to work at extensive frequency ranges with higher maximum operating frequency (f max.). The effects of different process, voltage and the temperature (PVT) variations are extensively evaluated by Monte-Carlo simulation. According to the results, the proposed circuit is robust against PVT variations and also noise-tolerable parameter. Moreover, the proposed RMC architecture is used in images applications. The results show that output images of the proposed inexact RMC have a very high quality and resemblance to the images generated by exact RMC, thus excellent values for the peak signal-to-noise ratio (PSNR) and mean structural similarity index metric (MSSIM) indicate that the proposed inexact RMC circuit has a proper accuracy for applications such as: comparative analysis in medical images, motion detector, edge detection and segmentation in nano-technology. Therefore, using the proposed scheme can be improved in comparator circuit in chips for future generation of VLSI and ULSI blocks, like: nano-processors performance. [ABSTRACT FROM AUTHOR]