A Study on the Energy Sustainability of Early Exit Networks for Human Activity Recognition

IF 3 3区 计算机科学 Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE
Emanuele Lattanzi;Chiara Contoli;Valerio Freschi
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引用次数: 0

Abstract

The design of IoT systems supporting deep learning capabilities is mainly based today on data transmission to the cloud back-end. Recently, edge computing solutions, which keep most computing and communication as close as possible to user devices have emerged as possible alternatives to reduce energy consumption, limit latency, and safeguard privacy. Early-exit models have been proposed as a way to combine models with different depths into a single architecture. The aim of this article is to investigate the energy expenditure of a distributed IoT system based on early exit architectures, by taking human activity recognition as a case study. We propose a simulation study based on an analytical model and hardware characterization to estimate the trade-off between the accuracy and energy of early exit-based configurations. Experimental results highlight nontrivial relationships between architectures, computing platforms, and communication link. For instance, we found that early-exit strategies do not ensure energy reductions with respect to a cloud-based solution if the same accuracy levels are kept; nonetheless, by tolerating a 1.5% decrease in accuracy, it is possible to achieve a reduction of around 40% of the total energy consumption.
人类活动识别早期退出网络的能源可持续性研究
目前,支持深度学习功能的物联网系统设计主要基于向云后端传输数据。最近,为了降低能耗、限制延迟和保护隐私,边缘计算解决方案应运而生,这种方案能让大部分计算和通信尽可能靠近用户设备。有人提出了早期退出模型,以此将不同深度的模型结合到单一架构中。本文旨在以人类活动识别为例,研究基于早期退出架构的分布式物联网系统的能耗。我们提出了一项基于分析模型和硬件特征的仿真研究,以估算基于早期退出配置的准确性和能耗之间的权衡。实验结果凸显了架构、计算平台和通信链路之间的非对称关系。例如,我们发现,与基于云的解决方案相比,如果保持相同的精度水平,提前退出策略并不能确保降低能耗;然而,通过容忍精度下降 1.5%,可以实现总能耗降低约 40%。
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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