Design and performance analysis of an ultra‐high‐speed 5‐2 compressor

Abstract: A novel ultra‐high‐speed 5‐2 compressor is presented and discussed in this paper. The proposed structure is developed by modifying the truth table focusing on the carry rippling problem. By reducing the number of the states in the truth table and the complexity of the structure, the total delay is reduced while the power and active area are also improved. The proposed compressor is compared with the best recently reported ones where the designed architecture shows 9%–80% improvement in power delay product (PDP… Show more

“…During recent years, various gate‐level and transistor‐level architectures have been offered for 4:2 and 5:2 compressors [17–19] with different techniques such as the gate‐diffusion input (GDI) by considering area reduction and output swing cost [20]. Also, the complementary metal‐oxide‐semiconductor (CMOS) was considered to improve the speed of these compressors (even for the 7:2 compressor) by resolving the carry rippling problem [21, 22]. The second one is characterised by the driving capability and robustness against process variation with large area occupation cost.…”

Tolerant and low power subtractor with 4:2 compressor and a new TG‐PTL‐float full adder cell

“…During recent years, various gate‐level and transistor‐level architectures have been offered for 4:2 and 5:2 compressors [17–19] with different techniques such as the gate‐diffusion input (GDI) by considering area reduction and output swing cost [20]. Also, the complementary metal‐oxide‐semiconductor (CMOS) was considered to improve the speed of these compressors (even for the 7:2 compressor) by resolving the carry rippling problem [21, 22]. The second one is characterised by the driving capability and robustness against process variation with large area occupation cost.…”

Tolerant and low power subtractor with 4:2 compressor and a new TG‐PTL‐float full adder cell

A novel multiplier-less convolution core for YOLO CNN ASIC implementation