A Regression Method With Subnetwork Neurons for Vigilance Estimation Using EOG and EEG

Wu, Wei; Wu, Qi; Sun, Wei; Yang, Yimin; Yuan, Xiaofang; Zheng, Wei‐Long; Lu, Bao-Liang

doi:10.1109/tcds.2018.2889223

Cited by 43 publications

(15 citation statements)

References 65 publications

(88 reference statements)

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“…In this study, eight feature level fusion methods were selected for comparison, including SVR, CCNF and CCRF [2], DAE [3], GELM [15], LSTM [16], DNNSN [17], and LSTM-CapsAtt [14]. The DNNSN proposes a double-layer neural network with subnetwork nodes.…”

Section: Comparison Methodsmentioning

confidence: 99%

“…This method explores time-dependent information and significantly improves the performance of vigilance estimation. The authors of [17] proposed a double-layered neural network with subnetwork nodes (DNNSN), which is composed of several subnet nodes, and each node is composed of many hidden nodes with various feature selection capabilities. Zhang [14] suggested that the capsule attention model and deep LSTM should be integrated with EEG and EEG.…”

Section: Introductionmentioning

confidence: 99%

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Deep Coupling Recurrent Auto-Encoder with Multi-Modal EEG and EOG for Vigilance Estimation

Song

Zhou

Wang

2021

Entropy

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Vigilance estimation of drivers is a hot research field of current traffic safety. Wearable devices can monitor information regarding the driver’s state in real time, which is then analyzed by a data analysis model to provide an estimation of vigilance. The accuracy of the data analysis model directly affects the effect of vigilance estimation. In this paper, we propose a deep coupling recurrent auto-encoder (DCRA) that combines electroencephalography (EEG) and electrooculography (EOG). This model uses a coupling layer to connect two single-modal auto-encoders to construct a joint objective loss function optimization model, which consists of single-modal loss and multi-modal loss. The single-modal loss is measured by Euclidean distance, and the multi-modal loss is measured by a Mahalanobis distance of metric learning, which can effectively reflect the distance between different modal data so that the distance between different modes can be described more accurately in the new feature space based on the metric matrix. In order to ensure gradient stability in the long sequence learning process, a multi-layer gated recurrent unit (GRU) auto-encoder model was adopted. The DCRA integrates data feature extraction and feature fusion. Relevant comparative experiments show that the DCRA is better than the single-modal method and the latest multi-modal fusion. The DCRA has a lower root mean square error (RMSE) and a higher Pearson correlation coefficient (PCC).

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Section: Comparison Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Deep Coupling Recurrent Auto-Encoder with Multi-Modal EEG and EOG for Vigilance Estimation

Song

Zhou

Wang

2021

Entropy

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“…In [13], the use of an LSTM network resulted in a considerable improvement using feature fusion over single-mode EEG and EOG. In [12], a Doublelayered Neural Network with Subnetwork Nodes (DNNSN) was utilized along with multimodal feature selection using an autoencoder, obtaining impressive results. In [29], two domain adaption networks, notably Domain-Adversarial Neural Network (DANN) and Adversarial Discriminative Domain Adaptation (ADDA) were employed with feature fusion.…”

Section: Related Workmentioning

confidence: 99%

“…Moreover, EEG and EOG are susceptible to artifacts caused by motion and muscle activity such as jaw motion, frowning, and others, making their interpretation particularly challenging [14], [15]. Lastly, multimodal analysis of biological signals is generally difficult since identifying the complementary and contradicting information in the available signals is a challenging [12].…”

Section: Introductionmentioning

confidence: 99%

Capsule Attention for Multimodal EEG-EOG Representation Learning With Application to Driver Vigilance Estimation

Zhang

Etemad

2021

IEEE Trans. Neural Syst. Rehabil. Eng.

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Driver vigilance estimation is an important task for transportation safety. Wearable and portable brain-computer interface devices provide a powerful means for real-time monitoring of the vigilance level of drivers to help with avoiding distracted or impaired driving. In this paper, we propose a novel multimodal architecture for in-vehicle vigilance estimation from Electroencephalogram and Electrooculogram. To enable the system to focus on the most salient parts of the learned multimodal representations, we propose an architecture composed of a capsule attention mechanism following a deep Long Short-Term Memory (LSTM) network. Our model learns hierarchical dependencies in the data through the LSTM and capsule feature representation layers. To better explore the discriminative ability of the learned representations, we study the effect of the proposed capsule attention mechanism including the number of dynamic routing iterations as well as other parameters. Experiments show the robustness of our method by outperforming other solutions and baseline techniques, setting a new state-of-the-art. We then provide an analysis on different frequency bands and brain regions to evaluate their suitability for driver vigilance estimation. Lastly, an analysis on the role of capsule attention, multimodality, and robustness to noise is performed, highlighting the advantages of our approach.

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“…A variety of deep learning techniques have been used to learn the most discriminative features extracted from EEG for affective computing. For example, In [7], the authors adopted Double-Layered Neural Network with Subnetwork Nodes (DNNSN) to estimate drivers' vigilance levels . In [8], a Graph regularized Extreme Learning Machine (GELM) was employed to predict fatigue .…”

Section: Related Workmentioning

confidence: 99%

Distilling EEG Representations via Capsules for Affective Computing

Zhang¹,

Etemad²

2021

Preprint

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Affective computing with Electroencephalogram (EEG) is a challenging task that requires cumbersome models to effectively learn the information contained in large-scale EEG signals, causing difficulties for real-time smart-device deployment. In this paper, we propose a novel knowledge distillation pipeline to distill EEG representations via capsule-based architectures for both classification and regression tasks. Our goal is to distill information from a heavy model to a lightweight model for subject-specific tasks. To this end, we first pre-train a large model (teacher network) on large number of training samples. Then, we employ the teacher network to learn the discriminative features embedded in capsules by adopting a lightweight model (student network) to mimic the teacher using the privileged knowledge. Such privileged information learned by the teacher contain similarities among capsules and are only available during the training stage of the student network. We evaluate the proposed architecture on two large-scale public EEG datasets, showing that our framework consistently enables student networks with different compression ratios to effectively learn from the teacher, even when provided with limited training samples. Lastly, our method achieves state-of-the-art results on one of the two datasets.

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A Regression Method With Subnetwork Neurons for Vigilance Estimation Using EOG and EEG

Cited by 43 publications

References 65 publications

Deep Coupling Recurrent Auto-Encoder with Multi-Modal EEG and EOG for Vigilance Estimation

Deep Coupling Recurrent Auto-Encoder with Multi-Modal EEG and EOG for Vigilance Estimation

Capsule Attention for Multimodal EEG-EOG Representation Learning With Application to Driver Vigilance Estimation

Distilling EEG Representations via Capsules for Affective Computing

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