Effective RCA design using quantum dot cellular automata

Abstract

Quantum dot Cellular Automata (QCA) is a transistor less technology alternative to CMOS for developing low-power, high speed digital circuits. Adder circuits are broadly employed in all digital computation systems. In this paper, a novel coplanar QCA full adder circuit is proposed which is designed with minimum number of QCA cells. The proposed full adder requires only 13 QCA cells, an area of 0.008 μm2 and delay of about 2 clock cycles to implement its function. Then an efficient 4-bit Ripple Carry Adder (RCA) is designed based on the proposed full adder that performs higher end addition in an effective way. Simulations results are obtained precisely using QCA designer tool version 2.0.3. Also the simulation results shows that the proposed 4-bit Ripple Carry Adder (RCA) requires only 70 QCA cells, an area of 0.18 μm2 and delay of about 5 clock cycles to implement its function with enhanced performance in terms of latency, area and QCA Cost. From the comparisons, it is found that our work achieves over 55% improvement in QCA cell count.