EEG-fNIRS-based hybrid image construction and classification using CNN-LSTM

Mughal, Nabeeha Ehsan; Khan, Muhammad Jawad; Khalil, Khurram; Javed, Kashif; Sajid, Hasan; Naseer, Noman; Ghafoor, Usman; Hong, Keum‐Shik

doi:10.3389/fnbot.2022.873239

Cited by 14 publications

(7 citation statements)

References 69 publications

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“…The present study validates the advantages of a hybrid neural-machine interface (Mughal et al, 2022 ). The hybridization of two distinct modalities resulted in stable output performance, unlike the results reported in published studies for a single modality source.…”

Section: Control Scheme For Prosthetic Arm Devicesupporting

confidence: 88%

Deep learning-based framework for real-time upper limb motion intention classification using combined bio-signals

Syed,

Sattar,

Ganiyu

et al. 2023

Front. Neurorobot.

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This research study proposes a unique framework that takes input from a surface electromyogram (sEMG) and functional near-infrared spectroscopy (fNIRS) bio-signals. These signals are trained using convolutional neural networks (CNN). The framework entails a real-time neuro-machine interface to decode the human intention of upper limb motions. The bio-signals from the two modalities are recorded for eight movements simultaneously for prosthetic arm functions focusing on trans-humeral amputees. The fNIRS signals are acquired from the human motor cortex, while sEMG is recorded from the human bicep muscles. The selected classification and command generation features are the peak, minimum, and mean ΔHbO and ΔHbR values within a 2-s moving window. In the case of sEMG, wavelength, peak, and mean were extracted with a 150-ms moving window. It was found that this scheme generates eight motions with an enhanced average accuracy of 94.5%. The obtained results validate the adopted research methodology and potential for future real-time neural-machine interfaces to control prosthetic arms.

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Section: Control Scheme For Prosthetic Arm Devicesupporting

confidence: 88%

Deep learning-based framework for real-time upper limb motion intention classification using combined bio-signals

Syed,

Sattar,

Ganiyu

et al. 2023

Front. Neurorobot.

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“…In recent times, DL has achieved remarkable performance across various fields due to its ability to extract underlying features from signals, thus mitigating the necessity for manual feature engineering. The Convolutional Neural Network (CNN) has found extensive usage in classifying Euclidean-structured signals, credited to its capability to learn informative features through local receptive fields (Du Y. et al, 2022;Mughal et al, 2022;de Oliveira and Rodrigues, 2023). Tang et al (2023a) developed a Multi-Scale Hybrid CNN to isolate temporal and spatial EEG signal attributes.…”

Section: Feature Extractionmentioning

confidence: 99%

Graph neural network based on brain inspired forward-forward mechanism for motor imagery classification in brain-computer interfaces

Xue,

Song,

et al. 2024

Front. Neurosci.

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IntroductionWithin the development of brain-computer interface (BCI) systems, it is crucial to consider the impact of brain network dynamics and neural signal transmission mechanisms on electroencephalogram-based motor imagery (MI-EEG) tasks. However, conventional deep learning (DL) methods cannot reflect the topological relationship among electrodes, thereby hindering the effective decoding of brain activity.MethodsInspired by the concept of brain neuronal forward-forward (F-F) mechanism, a novel DL framework based on Graph Neural Network combined forward-forward mechanism (F-FGCN) is presented. F-FGCN framework aims to enhance EEG signal decoding performance by applying functional topological relationships and signal propagation mechanism. The fusion process involves converting the multi-channel EEG into a sequence of signals and constructing a network grounded on the Pearson correlation coeffcient, effectively representing the associations between channels. Our model initially pre-trains the Graph Convolutional Network (GCN), and fine-tunes the output layer to obtain the feature vector. Moreover, the F-F model is used for advanced feature extraction and classification.Results and discussionAchievement of F-FGCN is assessed on the PhysioNet dataset for a four-class categorization, compared with various classical and state-of-the-art models. The learned features of the F-FGCN substantially amplify the performance of downstream classifiers, achieving the highest accuracy of 96.11% and 82.37% at the subject and group levels, respectively. Experimental results affirm the potency of FFGCN in enhancing EEG decoding performance, thus paving the way for BCI applications.

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“…Huve et al [28] implemented classification based on support vector machine (SVM), long short-term memory (LSTM), and LDA for tasks such as counting, arithmetic, and solving puzzles. Classification of the fNIRS signal based on three mental tasks such as rest state, subtraction, and generation of words using LSTM and CNN was studied by Asgher [29,30]; their results were improved and compared to classical machine learning methods [31]. Recurrent CNN showed classification of both time and spatial signals with good accuracy of EEG signals [32].…”

Section: Literature Reviewmentioning

confidence: 99%

Novel Feature Generation for Classification of Motor Activity from Functional Near-Infrared Spectroscopy Signals Using Machine Learning

Akila,

Christaline,

Edward

2024

Diagnostics

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Recent research in the field of cognitive motor action decoding focuses on data acquired from Functional Near-Infrared Spectroscopy (fNIRS) and its analysis. This research aims to classify two different motor activities, namely, mental drawing (MD) and spatial navigation (SN), using fNIRS data from non-motor baseline data and other motor activities. Accurate activity detection in non-stationary signals like fNIRS is challenging and requires complex feature descriptors. As a novel framework, a new feature generation by fusion of wavelet feature, Hilbert, symlet, and Hjorth parameters is proposed for improving the accuracy of the classification. This new fused feature has statistical descriptor elements, time-localization in the frequency domain, edge feature, texture features, and phase information to detect and locate the activity accurately. Three types of independent component analysis, including FastICA, Picard, and Infomax were implemented for preprocessing which removes noises and motion artifacts. Two independent binary classifiers are designed to handle the complexity of classification in which one is responsible for mental drawing (MD) detection and the other one is spatial navigation (SN). Four different types of algorithms including nearest neighbors (KNN), Linear Discriminant Analysis (LDA), light gradient-boosting machine (LGBM), and Extreme Gradient Boosting (XGBOOST) were implemented. It has been identified that the LGBM classifier gives high accuracies—98% for mental drawing and 97% for spatial navigation. Comparison with existing research proves that the proposed method gives the highest classification accuracies. Statistical validation of the proposed new feature generation by the Kruskal–Wallis H-test and Mann–Whitney U non-parametric test proves the reliability of the proposed mechanism.

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EEG-fNIRS-based hybrid image construction and classification using CNN-LSTM

Cited by 14 publications

References 69 publications

Deep learning-based framework for real-time upper limb motion intention classification using combined bio-signals

Deep learning-based framework for real-time upper limb motion intention classification using combined bio-signals

Graph neural network based on brain inspired forward-forward mechanism for motor imagery classification in brain-computer interfaces

Novel Feature Generation for Classification of Motor Activity from Functional Near-Infrared Spectroscopy Signals Using Machine Learning

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