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无线传感器网络中低功耗微控制器上的分散式分布式顺序神经网络推理:一个预测性维护案例研究

Decentralized Distributed Sequential Neural Networks Inference on Low-Power Microcontrollers in Wireless Sensor Networks: A Predictive Maintenance Case Study.

作者信息

Bolat Yernazar, Murray Iain, Ren Yifei, Ferdosian Nasim

机构信息

School of Electrical Engineering, Computing and Mathematical Sciences, Curtin University, Perth, WA 6102, Australia.

School of Minerals, Energy, and Chemical Engineering, Curtin University, Perth, WA 6102, Australia.

出版信息

Sensors (Basel). 2025 Jul 24;25(15):4595. doi: 10.3390/s25154595.

DOI:10.3390/s25154595
PMID:40807761
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12349209/
Abstract

The growing adoption of IoT applications has led to increased use of low-power microcontroller units (MCUs) for energy-efficient, local data processing. However, deploying deep neural networks (DNNs) on these constrained devices is challenging due to limitations in memory, computational power, and energy. Traditional methods like cloud-based inference and model compression often incur bandwidth, privacy, and accuracy trade-offs. This paper introduces a novel Decentralized Distributed Sequential Neural Network (DDSNN) designed for low-power MCUs in Tiny Machine Learning (TinyML) applications. Unlike the existing methods that rely on centralized cluster-based approaches, DDSNN partitions a pre-trained LeNet across multiple MCUs, enabling fully decentralized inference in wireless sensor networks (WSNs). We validate DDSNN in a real-world predictive maintenance scenario, where vibration data from an industrial pump is analyzed in real-time. The experimental results demonstrate that DDSNN achieves 99.01% accuracy, explicitly maintaining the accuracy of the non-distributed baseline model and reducing inference latency by approximately 50%, highlighting its significant enhancement over traditional, non-distributed approaches, demonstrating its practical feasibility under realistic operating conditions.

摘要

物联网应用的日益普及导致低功耗微控制器单元(MCU)在节能本地数据处理中的使用增加。然而,由于内存、计算能力和能源方面的限制,在这些受限设备上部署深度神经网络(DNN)具有很大挑战性。基于云的推理和模型压缩等传统方法往往需要在带宽、隐私性和准确性之间进行权衡。本文介绍了一种新颖的去中心化分布式顺序神经网络(DDSNN),专为微机器学习(TinyML)应用中的低功耗MCU设计。与现有的依赖基于集中式集群方法不同,DDSNN将预训练的LeNet划分到多个MCU上,从而在无线传感器网络(WSN)中实现完全去中心化推理。我们在实际的预测性维护场景中验证了DDSNN,在该场景中实时分析来自工业泵的振动数据。实验结果表明,DDSNN实现了99.01%的准确率,明确保持了非分布式基线模型的准确率,并将推理延迟降低了约50%,突出了其相对于传统非分布式方法的显著改进,证明了其在实际运行条件下的实际可行性。

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