Gate diffusion input based 4‐bit Vedic multiplier design

Garg, Ankit; Joshi, Garima

doi:10.1049/iet-cds.2017.0454

Cited by 21 publications

(2 citation statements)

References 20 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…GDI method was first introduced in [59] which later became a popular method for VLSI circuit design [60]. Logic implementation using the GDI technique can be realized from [61], where basic logic gates using the GDI technique, have been presented. The major issue regarding GDI methodbased circuit is its voltage degradation which reduces drive capability significantly [62].…”

Section: Hybrid Logic Full Addersmentioning

confidence: 99%

Comprehensive study of 1-Bit full adder cells: review, performance comparison and scalability analysis

et al. 2021

View full text Add to dashboard Cite

Full Adder (FA) circuits are integral components in the design of Arithmetic Logic Units (ALUs) of modern computing systems. Recently, there have been massive research interests in this area due to the growing need for low-power and high-performance computing systems. Researchers have proposed a variety of FA cells with diverse design techniques, each having its pros and cons. As a result, a systematic method for performance comparison of FA cells using a common simulation platform has become necessary. In this work, we present an extensive study of FA cells. We have compared the performance of thirty-three (33) existing 1-bit FA cells. The drive powers of these FA cells have been compared by applying a variety of load conditions. In addition, the 1-bit FA cells have been extended to 32-bit structures to test their scalability and to investigate their performance in wide-word structures. We have determined that twenty-one (21) of the thirty-three (33) FA cells cannot operate in a 32-bit structure, even though some of them exhibit excellent performance as a 1-bit cell. The main finding of this research is that the single-bit performance parameters of FA cells should not be considered as the main basis for performance comparison. Any FA cell should be analyzed in a multi-bit structure to determine its practical effectiveness.

show abstract

Section: Hybrid Logic Full Addersmentioning

confidence: 99%

Comprehensive study of 1-Bit full adder cells: review, performance comparison and scalability analysis

et al. 2021

View full text Add to dashboard Cite

show abstract

“…Adding binary numbers in one of the key operations of ALU [12]. Moreover, binary multiplication, subtraction and division requires addition of binary bits [13][14][15]. Hence, performance optimization of adder circuit would bring about overall impact on the performance of ALU [16].…”

Section: Introductionmentioning

confidence: 99%

Performance Improvement of 4-Bit Static CMOS Carry Look-Ahead Adder Using Modified Circuits for Carry Propagate and Generate Terms

Hasan¹,

Islam²,

Ahmed³

2019

CSSP

View full text Add to dashboard Cite

Carry Look-Ahead Adder (CLA) is considered as one of the most widely used adder topologies which are used in high performance computing systems. In this research, an improved version of 4-bit CLA adder has been proposed. Performance improvement of 4-bit CLA adder has been made by using hybrid AND and XOR gates in the input side for generating carry propagate and carry generate terms. The CLA circuits are kept exactly the same as the conventional one. Performance of the proposed modified 4-bit CLA adder has been evaluated and compared with the conventional design using Cadence tools in 90 nm technology node. Performance has been evaluated and compared in terms of average power, propagation delay and power delay product. The proposed modified design exhibited significant improvement in performance while compared with the conventional one. Enhancement done by the proposed 4-bit CLA adder design in average power, propagation delay and PDP were 14.96%, 11.76% and 25.32% respectively. In addition to performance enhancement, transistor count require for the proposed design is quite less compared to the conventional design which result in less surface area on chip. Moreover, less transistor count accounts for less power dissipation. Hence, utilizing the proposed design in modern high-performance computing systems would bring about high-performance improvements.

show abstract