International Journal of Engineering and Management Research (IJEMR)
  • Year: 2015
  • Volume: 5
  • Issue: 2

Design Advance Wallace Tree Multiplier with CSKA

  • Author:
  • Preeti Hooda1, Sachin Kumar2
  • Total Page Count: 4
  • Page Number: 738 to 741

1M. Tech in ECE Department, MERI College of Engineering& Technology, Sampla, India

2Assistant Professor in ECE Department, MERI College of Engineering& Technology, Sampla, India

Online published on 21 November, 2017.

Abstract

A multiplier is one of the key hardware blocks in most digital and high performance systems such as FIR filters, digital signal processors and microprocessors etc. With advances in technology, many researchers have tried and are trying to design multipliers which offer either of the following-high speed, low power consumption, regularity of layout and hence less area or even combination of them in multiplier. Thus making them suitable for various high speed, low power, and compact VLSI implementations. However area and speed are two conflicting constraints. So improving speed results always in larger areas. So here we try to find out the best trade off solution among the both of them. Generally as we know multiplication goes in two basic steps. Partial product and then addition. Hence in this paper we have first tried to design different adders and compare their speed and complexity of circuit i.e. the area occupied. While comparing the adders we found out that Ripple Carry Adder had a smaller area while having lesser speed, in contrast to which Carry Skip Adder are high speed but possess a larger area. And a Carry Look Ahead Adder is in between the spectrum having a proper trade-off between time and area complexities. After designing and comparing the adders we turned to multipliers. Initially we went for Parallel Multiplier and then Wallace Tree Multiplier. In the mean time we learned that delay amount was considerably reduced when Carry Skip Adders were used in Wallace Tree applications.

Keywords

Carry Skip Adder(CSKA), Multiplier(MR), Multiplicand(MD), Wallace Structure