ENF-S: An Evolutionary-Neuro-Fuzzy Multi-Objective Task Scheduler for Heterogeneous Multi-Core Processors

IF 3 3区 计算机科学 Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE
Athena Abdi;Armin Salimi-Badr
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引用次数: 0

Abstract

In this paper, an evolutionary-neuro-fuzzy-based task scheduling approach (ENF-S) to jointly optimize the main critical parameters of heterogeneous multi-core systems is proposed. This approach has two phases: first, the fuzzy neural network (FNN) is trained using a non-dominated sorting genetic algorithm (NSGA-II), considering the critical parameters of heterogeneous multi-core systems on a training data set consisting of different application graphs. These critical parameters are execution time, temperature, failure rate, and power consumption. The output of the trained FNN determines the criticality degree for various processing cores based on the system's current state. Next, the trained FNN is employed as an online scheduler to jointly optimize the critical objectives of multi-core systems at runtime. Due to the uncertainty in sensor measurements and the difference between computational models and reality, applying the fuzzy neural network is advantageous. The efficiency of ENF-S is investigated in various aspects including its joint optimization capability, appropriateness of generated fuzzy rules, comparison with related research, and its overhead analysis through several experiments on real-world and synthetic application graphs. Based on these experiments, our ENF-S outperforms the related studies in optimizing all design criteria. Its improvements over related methods are estimated ${19.21\%}$ in execution time, ${13.07\%}$ in temperature, ${25.09\%}$ in failure rate, and ${13.16\%}$ in power consumption, averagely.
ENF-S:一种用于异构多核处理器的进化神经模糊多目标任务调度器
本文提出了一种基于进化神经模糊的任务调度方法(ENF-S),用于联合优化异构多核系统的主要关键参数。该方法分为两个阶段:首先,在由不同应用图组成的训练数据集上,考虑异构多核系统的关键参数,使用非支配排序遗传算法(NSGA-II)训练模糊神经网络(FNN)。这些关键参数是执行时间、温度、故障率和功耗。经过训练的FNN的输出基于系统的当前状态来确定各种处理核心的关键程度。接下来,将经过训练的FNN用作在线调度器,以在运行时联合优化多核系统的关键目标。由于传感器测量的不确定性以及计算模型与实际情况的差异,应用模糊神经网络是有利的。通过在真实世界和合成应用图上的几个实验,从多个方面研究了ENF-S的效率,包括其联合优化能力、生成的模糊规则的适当性、与相关研究的比较以及其开销分析。基于这些实验,我们的ENF-S在优化所有设计标准方面优于相关研究。它相对于相关方法的改进估计为执行时间平均为${19.21\%}$,温度平均为${13.07%}$,故障率平均为${25.09\%}$,功耗平均为${13.16\%}$。
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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来源期刊
IEEE Transactions on Sustainable Computing
IEEE Transactions on Sustainable Computing Mathematics-Control and Optimization
CiteScore
7.70
自引率
2.60%
发文量
54
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