Power Efficient and High Speed Carry Skip Adder using Binary to Excess One Converter

The design of high-speed and low-power VLSI architectures need efficient arithmetic processing units, which are optimized for the performance parameters, namely, speed and power consumption. Adders are the key components in general purpose microprocessors and digital signal processors. As a result, it is very pertinent that its performance augers well for their speed performance. Additionally, the area is an essential factor which is to be taken into account in the design of fast adders. Towards this end, high-speed, low power and area efficient addition and multiplication have always been a fundamental requirement of high-performance processors and systems. The major speed limitation of adders arises from the huge carry propagation delay encountered in the conventional adder circuits, such as ripple carry adder and carry save adder. Observing that a carry may skip any addition stages on certain addend and augend bit values, researchers developed the carry-skip technique to speed up addition in the carry-ripple adder. Using a multilevel structure, carry-skip logic determines whether a carry entering one block may skip the next group of blocks. Because multilevel skip logic introduces longer delays, Therefore, in this paper we examine The basic idea of this work is to use Binary to Excess- 1 converter (BEC) instead of RCA with Cin=1 in conventional CSkA in order to reduce the area and power. BEC uses less number of logic gates than N-bit full adder.