An Approximate Carry Disregard Multiplier with Improved Mean Relative Error Distance and Probability of Correctness

Nowadays, a wide range of applications can tolerate certain computational errors. Hence, approximate computing has become one of the most attractive topics in computer architecture. Reducing accuracy in computations in a premeditated and appropriate manner reduces architectural complexities, and as a result, performance, power consumption, and area can improve significantly. This paper proposes a novel approximate multiplier design. The proposed design has been implemented using 45 nm CMOS technology and has been extensively evaluated. Compared to existing approximate architectures, the proposed approximate multiplier has higher accuracy. It also achieves better results in critical path delay, power consumption, and area up to 47.54 %, 75.24%, and 92.49%, respectively. Compared to the precise multipliers, our evaluations show that the critical path delay, power consumption, and area have been improved by 39%, 18%, and 6 %, respectively.