Implementation of Efficient Full Adder Using MVL Technique

The digital logic circuits are restricted for the requirement of interconnections. This difficulty overcomes by using a big set of signals over the same chip area. Multiple-valued logic (MVL) designs contain more importance from that perspective. This paper gives the fabrication of a multiple-valued half adder and full adder circuits. This technique advantageous for large scale circuits due to which large power dissipation with increased speed can lead to the development of extremely low energy circuit’s use for the high performance required for number of applications. Multiple-valued logic (MVL) designs are gaining more advantageous from the design of a multiple-valued half adder and full adder circuits. The presented adders are design in Multiple-Valued voltage-Mode Logic (MV-VML). In quaternary half adder, quaternary logic levels are exploited for the intention of addition. Addition operation is executed with minimum number of gates and less depth of net. The design is targeted for the 0.18 μm CMOS technology. Circuit is design by using Advanced Design System software {ADS software}. In this paper we try to find area, power and speed of the design HAq / FAq without any need of conversion, and compare to existing binary circuits [HAb / FAb].