MASER:利用状态空间建模提高脑电图空间分辨率。

IF 4.8 2区 医学 Q2 ENGINEERING, BIOMEDICAL
Yifan Zhang;Yang Yu;Hao Li;Anqi Wu;Ling-Li Zeng;Dewen Hu
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引用次数: 0

摘要

配备少量电极的消费级脑电图(EEG)设备通常空间分辨率较低,阻碍了对复杂大脑活动模式的准确捕捉。为解决这一问题,我们提出了一种用于脑电图记录的新型超分辨率方法 MASER。在 MASER 中,我们根据状态空间模型(SSM)的原理设计了用于提取脑电图特征的 eMamba 块。我们进一步堆叠 eMamba 块,形成低分辨率特征提取器和高分辨率信号预测器,从而增强了特征表示。在 MASER 的训练过程中,我们充分考虑了多维生物序列信号的特点,加入了平滑性约束损失,以实现更一致的高分辨率重构。MASER 首创了面向脑电图的状态空间建模,有效捕捉了时间动态和潜在状态,从而揭示了复杂的神经随时间变化的相互作用。大量实验表明,在两个公共脑电图数据集上,所提出的 MASER 的超分辨率质量优于最先进的方法,归一化均方误差降低了 16.25%,皮尔逊相关性提高了 1.13%。此外,一项关于运动图像识别的案例研究凸显了高分辨率脑电信号所带来的优势。通过 MASER 将空间分辨率提高 4 倍,识别准确率提高了 5.74%,这意味着脑机接口(BCI)指令映射的性能显著提高。通过提高脑电信号的空间分辨率,MASER 使基于脑电图的应用更加普及,降低了成本和设置时间,同时在游戏、教育和医疗保健等各个领域保持了高性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
MASER: Enhancing EEG Spatial Resolution With State Space Modeling
Consumer-grade Electroencephalography (EEG) devices equipped with few electrodes often suffer from low spatial resolution, hindering the accurate capture of intricate brain activity patterns. To address this issue, we propose MASER, a novel super-resolution approach for EEG recording. In MASER, we design the eMamba block for extracting EEG features based on the principles of state space models (SSMs). We further stack eMamba blocks to form a low-resolution feature extractor and a high-resolution signal predictor, which enhances the feature representation. During the training of MASER, we fully consider the characteristics of multidimensional biological series signals, incorporating a smoothness constraint loss to achieve more consistent high-resolution reconstructions. MASER pioneers EEG-oriented state space modeling, effectively capturing the temporal dynamics and latent states, thereby revealing complex neural interactions over time. Extensive experiments show that the proposed MASER outperforms the state-of-the-art methods in super-resolution quality on two public EEG datasets, with normalized mean square error reduced by 16.25% and Pearson correlation improved by 1.13%. Moreover, a case study of motor imagery recognition highlights the advantages conferred by high-resolution EEG signals. With a 4x increase in spatial resolution by MASER, the recognition accuracy improves by 5.74%, implying a significant performance elevation in brain-computer interface (BCI) command mapping. By enhancing the spatial resolution of EEG signals, MASER makes EEG-based applications more accessible, reducing cost and setup time while maintaining high performance across various domains such as gaming, education, and healthcare.
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来源期刊
CiteScore
8.60
自引率
8.20%
发文量
479
审稿时长
6-12 weeks
期刊介绍: Rehabilitative and neural aspects of biomedical engineering, including functional electrical stimulation, acoustic dynamics, human performance measurement and analysis, nerve stimulation, electromyography, motor control and stimulation; and hardware and software applications for rehabilitation engineering and assistive devices.
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