Convolutional Neural Network Based Electroencephalogram Controlled Robotic Arm

2021 IEEE International Conference on Automatic Control & Intelligent Systems (I2CACIS) Pub Date : 2021-06-26 DOI:10.1109/I2CACIS52118.2021.9495879

Z. Lim, Neo Yong Quan

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引用次数: 3

Abstract

In this paper, we present a six-degree of freedom (DOF) robotic arm that can be directly controlled by brainwaves, also known as electroencephalogram (EEG) signals. The EEG signals are acquired using an open-source device known as OpenBCI Ultracortex Mark IV Headset. In this research, inverse kinematics is implemented to simplify the controlling method of the robotic into 8 commands for the end-effector: forward, backward, upward, downward, left, right, open and close. A deep learning method namely convolutional neural network (CNN) which constructed using Python programming language is used to classify the EEG signals into 8 mental commands. The recall rate and precision of the 8 mental command classification using the CNN model in this research are up to 91.9% and 92%. The average inference time for the system is 1.5 seconds. Hence, this research offers a breakthrough technology that allows disabled persons for example paralyzed patients and upper limbs amputees to control a robotic arm to handle their daily life tasks.

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基于卷积神经网络的脑电图控制机械臂

在本文中，我们提出了一种可以通过脑电波(也称为脑电图(EEG)信号)直接控制的六自由度机械臂。脑电图信号是使用开源设备获取的，该设备被称为OpenBCI ultrortex Mark IV耳机。在本研究中，采用逆运动学的方法，将机器人的控制方法简化为末端执行器的8个命令:向前、向后、向上、向下、左、右、打开和关闭。利用Python编程语言构建卷积神经网络(convolutional neural network, CNN)作为深度学习方法，将EEG信号分类为8个心理指令。本研究中使用CNN模型对8个心理命令分类的查全率和查准率分别达到91.9%和92%。系统的平均推理时间为1.5秒。因此，这项研究提供了一项突破性的技术，可以让瘫痪患者和上肢截肢者等残疾人控制机械臂来处理他们的日常生活任务。

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2021 IEEE International Conference on Automatic Control & Intelligent Systems (I2CACIS)

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