Toward unsupervised Human Activity Recognition on Microcontroller Units

2020 23rd Euromicro Conference on Digital System Design (DSD) Pub Date : 2020-08-01 DOI:10.1109/DSD51259.2020.00090

Pierre-Emmanuel Novac, A. Castagnetti, A. Russo, Benoît Miramond, A. Pegatoquet, F. Verdier

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引用次数: 14

Abstract

Bringing artificial intelligence to embedded devices has become a central research topic in many scientific domains (environment, agriculture, sociology, health…). For Human Activity Recognition, Artificial Neural Networks (ANNs) have shown their capability to provide better performance compared to other machine learning methods. However, ANNs suffer from two major limitations. First, ANNs are often trained using supervised learning requiring labelled databases, which are often difficult to build in real applications. Then, those algorithms are usually very expensive in terms of computing power. For that reason, their integration into low-power microcontrollers has been so far only evaluated to a limited extent. In this paper, we propose to evaluate quantitatively and qualitatively the embedded implementation of different neural networks for human activity recognition. First, supervised learning approaches are presented, followed by an exploratory study of unsupervised learning approaches using Self-Organizing Maps. Finally, some aspects of embedded unsupervised online learning are investigated to improve classification results using subject-specific data over a more general training. Each neural network is tested on a Human Activity Recognition dataset acquired from a smartphone using accelerometer and gyroscope sensing information (UCI HAR) and deployed on the SparkFun Edge board. This board hosts a low-power ARM Cortex-M4F-based microcontroller.

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基于单片机的无监督人体活动识别研究

将人工智能引入嵌入式设备已经成为许多科学领域(环境、农业、社会学、健康……)的中心研究课题。对于人类活动识别，与其他机器学习方法相比，人工神经网络(ann)已经显示出其提供更好性能的能力。然而，人工神经网络有两个主要的局限性。首先，人工神经网络通常使用需要标记数据库的监督学习进行训练，这通常难以在实际应用中构建。然后，这些算法通常在计算能力方面非常昂贵。因此，到目前为止，它们与低功耗微控制器的集成仅在有限程度上进行了评估。在本文中，我们建议定量和定性地评估不同神经网络对人类活动识别的嵌入式实现。首先，提出了监督学习方法，然后对使用自组织地图的无监督学习方法进行了探索性研究。最后，对嵌入式无监督在线学习的一些方面进行了研究，以在更一般的训练中使用特定主题的数据来改进分类结果。每个神经网络都在使用加速度计和陀螺仪传感信息(UCI HAR)从智能手机获取的人类活动识别数据集上进行测试，并部署在SparkFun Edge板上。该板承载一个低功耗ARM cortex - m4f微控制器。

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

2020 23rd Euromicro Conference on Digital System Design (DSD)

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