Toward an autonomous Smart Home: a three-layer Edge-Fog-Cloud architecture with latency analysis

2021 IEEE 22nd International Conference on High Performance Switching and Routing (HPSR) Pub Date : 2021-06-07 DOI:10.1109/HPSR52026.2021.9481821

Hussein Chour, Djamel Eddine Kouicem, Azade Fotouhi, Mouna Ben Mabrouk

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引用次数: 1

Abstract

Due to the rapid evolution of smart devices, recently, the smart home (SH) sector has attracted attention and faced a fast expansion. However, the current cloud-based SH architecture and the ever-growth of the smart-things number and applications have brought several challenges to SH like the user-dependent automation tasks, the user-dependent SH management system, and the relatively large delay response time. These challenges create a gap between the actual SH and the envisioned autonomous SH that can control the SH objects independently and automate the home intelligently. Reducing this gap became the main target of the current SH research works. This paper builds on the network softwarization and virtualization techniques along with the edge, fog, and cloud computing to propose a three-layer Edge-Fog-Cloud SH (EFC-SH) intelligence architecture that can enable the autonomous SH. Then, it derives the optimal trade-off between the workload and the latency at each layer. Simulation results show that the proposed EFC-SH architecture achieves lower latency compared to the cloud-only or fog-only architectures.

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迈向自主智能家居:具有延迟分析的三层边缘雾云架构

由于智能设备的快速发展，近年来，智能家居行业受到关注并面临快速扩张。然而，当前基于云的智能家居架构以及智能物和智能应用的不断增长，给智能家居带来了依赖于用户的自动化任务、依赖于用户的智能家居管理系统以及相对较大的延迟响应时间等挑战。这些挑战在实际的智能家居和设想的自主智能家居之间造成了差距，后者可以独立控制智能家居对象并实现家居自动化。缩小这一差距成为当前SH研究工作的主要目标。本文以网络软件化和虚拟化技术为基础，结合边缘计算、雾计算和云计算，提出了一种能够实现自治SH的三层边缘-雾-云SH (EFC-SH)智能架构，并在每层的工作负载和延迟之间得出了最佳权衡。仿真结果表明，与纯云或纯雾架构相比，本文提出的EFC-SH架构具有更低的延迟。

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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2021 IEEE 22nd International Conference on High Performance Switching and Routing (HPSR)

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