Computationally Light Algorithms for Tactile Sensing Signals Elaboration and Classification

2021 28th IEEE International Conference on Electronics, Circuits, and Systems (ICECS) Pub Date : 2021-11-28 DOI:10.1109/icecs53924.2021.9665554

Youssef Amin, C. Gianoglio, M. Valle

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引用次数: 1

Abstract

Tactile sensing systems require embedded processing to extract structured information in many application domains as prosthetics and robotics. In this regard, this paper proposes computationally light strategies to pre-process the sensor signals and extract features, feeding single layer feed-forward neural networks (SLFNNs) that proved good generalization performance keeping low the computational cost. We validate our proposal by integrating a tactile sensing system on a Baxter robot to collect and classify data from three objects of different stiffness. We compare different features extraction techniques and five SLFNNs to show the trade-off between generalization accuracy and computational cost of the whole processing unit. The results show that the processing unit that extracts the mean and standard deviation features from signals and adopts a fully connected neural network (FCNN) with 50 neurons and ReLu activation function achieves a high accuracy (94.4%) in the 3-class classification problem with a low computational cost, leading to the deployment on a resource-constrained device.

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触觉感知信号精化与分类的计算光算法

在许多应用领域，如假肢和机器人，触觉传感系统需要嵌入式处理来提取结构化信息。在这方面，本文提出了计算轻量级的策略来预处理传感器信号和提取特征，并提供单层前馈神经网络(SLFNNs)，该网络具有良好的泛化性能，且计算成本低。我们通过在Baxter机器人上集成触觉传感系统来验证我们的建议，以收集和分类来自三个不同刚度物体的数据。我们比较了不同的特征提取技术和五种slfnn，以显示泛化精度和整个处理单元的计算成本之间的权衡。结果表明，从信号中提取均值和标准差特征的处理单元，采用50个神经元和ReLu激活函数的全连接神经网络(FCNN)，在3类分类问题中获得了较高的准确率(94.4%)，且计算成本较低，可以部署在资源受限的设备上。

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

2021 28th IEEE International Conference on Electronics, Circuits, and Systems (ICECS)

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