LOW POWER OPTIMIZATION OF FULL ADDER CIRCUIT BASED ON GDI LOGIC FOR BIOMEDICAL APPLICATIONS

Advanced Electronic Devices have recently become more prevalent, designers have opted for low power, quick speed, and compact designs and processes. Even though there are numerous design methodologies currently in use for VLSI system design optimization, very few design techniques produce solutions that are optimally optimal. GDI-based circuits are becoming increasingly important since they use less space, power, and energy. The GDI technique ensures minimal propagation delay, power, and area in low-power design strategies. For 45nm technology, the Cadence Virtuoso EDA tool is utilised to determine delay and power. The proposed designs examination of delay and power performance at 1.0V voltage produced positive findings. The Gate Diffusion Input concept serves as the foundation for the proposed design in this work. In order to achieve a full voltage swing of the output, a 1-bit full adder circuit design using GDI is demonstrated in this work. The GDI with the Full Swing Technique is presented in this work. Applying the suggested way to a 45nm complete adder from 14 Transistors. It is evident from the obtained simulation results that the suggested design uses the least power and the least amount of delay when compared to other full adder circuits that are already in use. Consequently, compared to previous full adder GDI circuit designs, the output voltage swing is in full and the overall power-delay product is improved by 60 percent.