节能RISC-V内核的不同微架构评估

J. Kadomoto, H. Irie, S. Sakai
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引用次数: 0

摘要

物联网应用的增加引发了可以利用有限能源的节能嵌入式soc的发展。相对简单的通用处理器内核是soc的重要组成部分,优化功耗、性能和面积是设计soc的关键问题。因此,本研究定量比较了几种不同微架构的32位RISC-V内核的功耗、性能和面积。对每个具有不同管道配置的处理器进行了仿真评估,有和没有乘法器和除法器。给出了寄存器传输级(RTL)设计的处理器的基准执行性能,以及基于逻辑合成和采用各种CMOS工艺技术的放置和布线的估计功耗和面积。基于这些结果,我们为节能嵌入式soc的微架构选择提供了一个简要的指导方针。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evaluation of Different Microarchitectures for Energy-Efficient RISC-V Cores
The increase in Internet of Things $(\text{IoT})$ applications has triggered the development of energy-efficient embedded SoCs that can utilize limited energy sources. Relatively simple general-purpose processor cores are a vital component of SoCs, and op-timizing the power consumption, performance, and area is a key issue in the design of $\text{SoCs}$. Therefore, this study quantitatively compared the power, performance, and area of several 32-bit RISC-V cores with different microarchitectures. The simulation evaluations were performed for each processor with different pipeline configurations, with and without a multiplier and divider. The benchmark execution performance of the processors in a register transfer level (RTL) design, as well as the estimated power consumption and area based on logic synthesis and place-and-route using various CMOS process technologies are presented. Based on the results, we provided a brief guideline for the selection of microarchitectures for energy-efficient embedded SoCs.
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