基于dropout层的双向LSTM运动图像信号分类研究

2022 International Conference on Advancement in Electrical and Electronic Engineering (ICAEEE) Pub Date : 2022-02-24 DOI:10.1109/icaeee54957.2022.9836415

Shadman Mahmood Khan Pathan, M. Rana

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引用次数: 1

摘要

虽然神经信号的分类对各种应用至关重要，但脑电图(EEG)信号的实际应用，例如轮椅控制，本质上是连续的。与循环神经网络(rnn)相比，长短期记忆(LSTM)算法在分析和学习更大范围的序列数据方面具有可行性。本文将一种新颖的LSTM模型设计应用于比参考文献更大的EEG数据集。在这项工作中，该模型在14个受试者的数据集上使用随机洗牌的十倍交叉验证实现了83%的准确性。而在参考文献中则考虑了个体受试者的准确性。由于在LSTM层之后应用dropout层，对于一个训练过程来说，数据的测试精度更高。使用Tensorflow 2.7.0版本在一个提供给Physionet的BCI2000标准数据集上实现。脑电信号的采样频率为160 Hz，信号历元的持续时间为4秒。使用Tensorflow 2.7.0版本在一个提供给Physionet的BCI2000标准数据集上实现。

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Investigation on classification of motor imagery signal using Bidirectional LSTM with effect of dropout layers

While classification of neural signals is critical for various applications, practical uses of Electroencephalography (EEG) signals, for example wheelchair control, are sequential in nature. The Long Short Term Memory (LSTM) algorithm is known for its feasibility in analysing and learning from longer ranges of sequential data than recurrent neural networks (RNNs). This work has applied a novel LSTM model design on an EEG dataset which is larger than a reference work. The model in this work has achieved an accuracy of 83% on a dataset of 14 subjects using randomly shuffled tenfold cross validation. Whereas in reference work accuracy of individual subjects were considered. The test accuracy of the data was found to be higher for a training process due to application of dropout layers after LSTM layers. The implementation was realized using Tensorflow version 2.7.0 on a dataset contributed to Physionet which was of BCI2000 standard. Sampling frequency of the EEG signal was 160 Hz and the duration of epoch of the signal is 4 seconds. The implementation was realized using Tensorflow version 2.7.0 on a dataset contributed to Physionet which was of BCI2000 standard.

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2022 International Conference on Advancement in Electrical and Electronic Engineering (ICAEEE)

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