Design of high speed hybrid carry select adder

2013 3rd IEEE International Advance Computing Conference (IACC) Pub Date : 2013-05-13 DOI:10.1109/IADCC.2013.6514477

S. Parmar, K. P. Singh

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引用次数: 97

Abstract

The paper describes the power and area efficient carry select adder (CSA). Firstly, CSA is one of the fastest adders used in many data-processing systems to perform fast arithmetic operations. Secondly, CSA is intermediate between small areas but longer delay Ripple Carry Adder (RCA) and a larger area with shorter delay carry look-ahead adder. Third, there is still scope to reduce area in CSA by introduction of some add-one scheme. In Modified Carry Select Adder (MCSA) design, single RCA and BEC are used instead of dual RCAs to reduce area and power consumption with small speed penalty. The reason for area reduction is that, the number of logic gates used to design a BEC is less than the number of logic gates used for a RCA design. Thus, importance of BEC logic comes from the large silicon area reduction when designing MCSA for large number of bits. MCSA architectures are designed for 8-bit, 16-bit, 32-bit and 64-bit respectively. The design has been synthesized at 90nm process technology targeting using Xilinx Spartan-3 device. Comparison results of modified CSA with conventional CSA show better results and improvements.

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高速混合进位选择加法器的设计

介绍了一种功率高效、面积高效的进位选择加法器。首先，CSA是许多数据处理系统中用于执行快速算术运算的最快加法器之一。其次，CSA介于小区域但延迟较长的纹波进位加法器(RCA)和大区域但延迟较短的进位预加法器之间。第三，通过引入一些加一方案，CSA仍有缩小面积的余地。在改进进位选择加法器(MCSA)设计中，采用单RCA和BEC代替双RCA，以减少面积和功耗，速度损失小。面积减少的原因是，用于设计BEC的逻辑门的数量少于用于RCA设计的逻辑门的数量。因此，BEC逻辑的重要性来自于在设计用于大量比特的MCSA时的大面积硅面积缩减。MCSA架构分别设计为8位、16位、32位和64位。该设计以90nm工艺技术为目标，采用Xilinx Spartan-3器件进行合成。改良CSA与常规CSA的对比结果显示出更好的效果和改进。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2013 3rd IEEE International Advance Computing Conference (IACC)

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