基于fNIRS-EEG混合的5级记忆负荷判别

C. Herff, Ole Fortmann, C. Tse, Xiaoqin Cheng, F. Putze, D. Heger, Tanja Schultz
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引用次数: 20

摘要

在这项研究中,我们发现脑电图(EEG)和功能近红外光谱(fNIRS)可以用来区分5个水平的记忆负荷。我们用内存更新任务诱导内存负载,这是已知的健壮地产生内存负载,并允许我们定义5个不同级别的负载。典型的实验只区分低负荷和高负荷或最多三个班。据我们所知,记忆更新任务之前还没有与大脑活动测量结合使用过。在这里,对于非常高和非常低的工作负载之间的二元分类,准确率高达93%。平均而言,区分两个级别的工作负载的准确率为74%。五个类别之间的分类平均准确率为44%。尽管EEG结果始终优于fNIRS结果,但我们可以证明,两种模式的特征级融合增加了分类结果的鲁棒性。对不同记忆负荷水平的可靠区分可以用来调整用户界面或向学习者呈现适当数量的信息。
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Hybrid fNIRS-EEG based discrimination of 5 levels of memory load
In this study, we show that both electroencephalograhy (EEG) and functional Near-Infrared Spectroscopy (fNIRS) can be used to discriminate between 5 levels of memory load. We induce memory load with the memory updating task, which is known to robustly generate memory load and allows us to define 5 different levels of load. Typical experiments only discriminate between low and high workload or up to a maximum of three classes. To the best of our knowledge, the memory updating task has not been used in combination with brain activity measurements before. Here, accuracies of up to 93% are achieved for the binary classification between very high and very low workload. On average, two levels of workload could be discriminated with 74% accuracy. Classification between the full five classes yielded 44% accuracy on average. Despite the fact that EEG results consistently outperformed the results obtained with fNIRS, we could show that the feature-level fusion of both modalities increased robustness of classification results. A reliable discrimination between different levels of memory load could be used to adapt user interfaces or present the right amount of information to a learner.
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