用于分析脑机接口中运动图像信号的多尺度自我注意力方法

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Applied Bio Materials Pub Date : 2024-05-23 DOI:10.1016/j.jneumeth.2024.110182

Mohammed Wasim Bhatt, Sparsh Sharma

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引用次数: 0

摘要

背景基于运动图像的脑电图（EEG）脑机接口（BCI）技术在过去几年取得了巨大进步。就生产率而言，深度学习优于更传统的方法，如新一代神经技术。开发和训练一个端到端网络，使其能够从用于运动成像的脑电图数据中充分提取可能的特征，仍然具有挑战性。脑机接口研究在很大程度上依赖于对脑电图数据进行准确分类这一基本问题。即使研究人员已经提出了多种方法，如深度学习和机器学习技术，但在运动成像分类领域仍存在许多挑战。方法论我们提供了一个利用注意力机制对运动成像脑电信号进行四级分类的模型：左手、右手、脚和舌头/休息。该模型建立在多尺度时空自我注意网络之上。为了确定最有效的通道，自我注意网络在空间上被实施，为与运动相关的通道分配更大的权重，为与运动无关的通道分配较小的权重。为了消除时域噪声，利用并行多尺度时域卷积网络（TCN）层来提取不同尺度的时域特征。26 %。与现有方法的比较在单个被试分类中，与现有方法相比，这种方法表现出更高的准确性。结论研究结果表明，这种方法表现出值得称赞的性能、复原力和迁移学习能力。

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Multi-scale self-attention approach for analysing motor imagery signals in brain-computer interfaces

Background

Motor imagery-based electroencephalogram (EEG) brain-computer interface (BCI) technology has seen tremendous advancements in the past several years. Deep learning has outperformed more traditional approaches, such next-gen neuro-technologies, in terms of productivity. It is still challenging to develop and train an end-to-end network that can sufficiently extract the possible characteristics from EEG data used in motor imaging. Brain-computer interface research is largely reliant on the fundamental problem of accurately classifying EEG data. There are still many challenges in the field of MI classification even after researchers have proposed a variety of methods, such as deep learning and machine learning techniques.

Methodology

We provide a model for four-class categorization of motor imagery EEG signals using attention mechanisms: left hand, right hand, foot, and tongue/rest. The model is built on multi-scale spatiotemporal self-attention networks. To determine the most effective channels, self-attention networks are implemented spatially to assign greater weight to channels associated with motion and lesser weight to channels unrelated to motion. To eliminate noise in the temporal domain, parallel multi-scale Temporal Convolutional Network (TCN) layers are utilized to extract temporal domain features at various scales.

Result

On the IV-2b dataset from the BCI Competition, the suggested model achieved an accuracy of 85.09 %; on the IV-2a and IV-2b datasets from the HGD datasets, it was 96.26 %.