In this paper, we propose a hybrid full-swing adder (HFSA) circuit that uses the hybrid full-swing logic (HFSL) technique, which consists of 20 transistors. This circuit relies heavily on a 12-transistor XOR-XNOR circuit to optimize the area and power. Our novel XOR-XNOR circuit plays a crucial role in achieving high-efficiency HFSA circuits. It integrates 2-to-1 multiplexers, pass transistor logic, and inverters to deliver glitch-free full-swing outputs. We compared the efficiency and practicality of our design with those of 10 alternatives by considering their performances and characteristics. Our novel XOR-XNOR circuit surpassed its counterparts with an exceptional chip area reduction of 14.14–28.01 %, an average power of 2.44 μW, and remarkably low delays of 25.88 and 24.87 ps. Notably, the proposed full adder achieved a chip area reduction of 11.30–49.69 %, 3.582 μW power, and a 72.66 ps delay. It emphasizes large-scale structures, such as 4-bit to 64-bit full adders, implemented using cascaded designs with a novel ripple carry adder. Using multipoint and Monte Carlo analysis in the ADEXL design suite to ensure the reliability of all circuits using the Cadence Virtuoso with the GPDK45 nm technology. The proposed method is an alternative to high-speed electronic systems with potential benefits.
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