A Novel Approximate Adder Design Using Error Reduced Carry Prediction and Constant Truncation

This paper proposes a novel approximate adder that exploits an error-reduced carry prediction and constant truncation with error reduction schemes. The proposed adder design techniques significantly improve overall computation accuracy while providing excellent hardware efficiency. Particularly, the proposed carry prediction technique can reduce a prediction error rate by up to 75% compared to existing approximate adders considered in this paper. Furthermore, the error reduction technique also enhances the overall computation accuracy by decreasing the error distance (ED). Our experimental results show that the proposed adder improves the normalized mean ED (NMED) and mean relative ED (MRED) by up to 91.4% and 98.9%, respectively, compared to the other approximate adders. Importantly, an excellent design tradeoff allows the proposed adder to be the most competitive of the adders under consideration. Specifically, the proposed adder achieves up to 95.7%, 91.1%, and 93.2% reductions of the power-NMED, energy-NMED, and area-delay product (ADP)-NMED products, respectively, compared to the other adders. Our adder enhances the power-, energy-, and ADP-MRED products by up to 99.4% compared to the others. In particular, the figure of merit (FoM) considering both hardware and accuracy of the proposed adder is up to 93.05% smaller than that of the other approximate adders considered herein. Furthermore, we confirm that the approximation errors caused by the proposed adder have very little impact on output quality when adopted in practical applications, such as digital image processing and machine learning.