A New Technology for Reducing Dynamic Power Consumption in 8-Bit ALU Design

Iraqi Journal of Industrial Research Pub Date : 2022-12-14 DOI:10.53523/ijoirvol9i3id279

Ahmed Lateef Hameed, Maan Hameed, Raed Abdulkareem Hasan

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Abstract

Clock gating is an effective way to decrease dissipated power in synchronous design. The most effective way to do this is by masking the clock that turns toward the unused part of design. In this paper, a comparative evaluation of power consumption in existing clock gating techniques in Arithmetic Logical Unit (ALU) design was achieved. an innovative signal clock gating method offers extra immunity in the direction of the present issue in an accessible mechanism. A Gated Clock Generation designs using a tri-state connection and logic gate, generated by the set of bubbled input with NAND gate, is used for the latest suggested clock gating. This design saves power even when the clock is at applying to the target module. Complete power analysis reveals that the proposed technique has an effect on the dynamic power that decreases total power consumption up to 24.90% relative to traditional power. All experiments are done in arithmetic logic unit design. 130 nm standard logic libraries have been used for implementation in order to achieve ALU frameworks. The ALU design architecture was developed using the Verilog HDL, and the simulations are performed utilizing ModelSim-Altera 10.0c (Quartus II 11.1) Starter Version.

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一种降低8位ALU动态功耗的新技术

时钟门控是同步设计中降低功耗的有效方法。最有效的方法是屏蔽转向设计中未使用部分的时钟。本文对算术逻辑单元(ALU)设计中现有时钟门控技术的功耗进行了比较评估。一种创新的信号时钟门控方法在可访问机制中为本问题的方向提供了额外的抗扰度。一种采用三态连接和逻辑门的门控时钟发生器设计，由一组带NAND门的冒泡输入产生，用于最新建议的时钟门控。这种设计即使在时钟应用于目标模块时也可以节省功耗。完全功率分析表明，该技术对动态功率的影响相对于传统功率降低了24.90%的总功耗。所有实验均在算术逻辑单元设计中完成。为了实现ALU框架，使用了130nm标准逻辑库进行实现。ALU设计架构使用Verilog HDL开发，仿真使用ModelSim-Altera 10.0c (Quartus II 11.1) Starter Version进行。

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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Iraqi Journal of Industrial Research

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