Comparative Analysis of CMOS based Full Adders by Simulation in DSCH and Microwind

Malaysian Journal of Science and Advanced Technology Pub Date : 2022-10-16 DOI:10.56532/mjsat.v2i4.63

Sehan Amandu Gamage, Krishnan Subramaniam, A. Zainuddin

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引用次数: 1

Abstract

The decrease of surface area is a critical concern for any type of digital circuit. For example, the VLSI approach is used to lower the chip's size, which increases both the device's density and its performance. When it comes to digital circuits, a full adder circuit is a crucial part of any arithmetic processor. A computer, or any other type of computer, will have this component. Most arithmetic operations performed as of now are 64 bits. As a result, we need a sizable amount of room to complete this procedure. We can also take use of these advantages even if we increase the number of bits that need to be processed in parallel. This research attempts to demonstrate how a 4-bit CMOS-based full adder circuit is designed and simulated using Microwind and DSCH at various technology levels. It is then compared to determine if the transistor size may help achieve those benefits. Afterwards. A four-bit binary addition is the goal of the circuit that was built. A 4-bit full adder may be built using a totally automated CMOS design process. The concept and layout of a 4-bit full adder are developed in the initial CMOS design. With nodes of 90, 65 and 45 nm, the designs are produced and modelled utilizing technology. Digital integrated circuits with smaller nodes perform better when compared to those with larger ones, according to simulation findings and distinct outputs.

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基于CMOS的全加法器在DSCH和Microwind中的仿真比较分析

对于任何类型的数字电路，表面积的减小都是一个关键问题。例如，VLSI方法用于降低芯片的尺寸，从而增加了器件的密度和性能。当涉及到数字电路时，一个完整的加法器电路是任何算术处理器的关键部分。一台计算机，或者任何其他类型的计算机，都会有这个组件。目前执行的大多数算术运算都是64位的。因此，我们需要相当大的空间来完成这一过程。即使我们增加了需要并行处理的比特数，我们也可以利用这些优势。本研究试图演示如何使用Microwind和DSCH在不同技术水平上设计和模拟基于4位cmos的全加法器电路。然后进行比较，以确定晶体管尺寸是否有助于实现这些好处。之后。一个4位二进制加法是电路的目标。一个4位全加法器可以使用完全自动化的CMOS设计过程来构建。在最初的CMOS设计中，开发了4位全加法器的概念和布局。节点分别为90nm、65nm和45nm，这些设计是利用技术生产和建模的。根据仿真结果和不同的输出，与具有较大节点的数字集成电路相比，具有较小节点的数字集成电路性能更好。

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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Malaysian Journal of Science and Advanced Technology

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