Reconstruction of missing channel in electroencephalogram using spatiotemporal correlation-based averaging

Bahador, Nooshin; Jokelainen, Jarno; Mustola, Seppo; Kortelainen, Jukka

doi:10.1088/1741-2552/ac23e2

Cited by 4 publications

(5 citation statements)

References 45 publications

(112 reference statements)

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“…Visualizing the reconstructed data and the real data, we observed that at most points the reconstructed data were close to the real values. However, when several bad channels are close to each other, the interpolation algorithm fits poorly at points with higher amplitudes, and a similar phenomenon was observed in the Bahador et al (2021) and Li et al (2022) experiments. This part of the data points causes a large reconstruction error.…”

Section: Discussionsupporting

confidence: 68%

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Assigning channel weights using an attention mechanism: an EEG interpolation algorithm

Liu,

Wang,

Qiu

et al. 2023

Front. Neurosci.

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During the acquisition of electroencephalographic (EEG) signals, various factors can influence the data and lead to the presence of one or multiple bad channels. Bad channel interpolation is the use of good channels data to reconstruct bad channel, thereby maintaining the original dimensions of the data for subsequent analysis tasks. The mainstream interpolation algorithm assigns weights to channels based on the physical distance of the electrodes and does not take into account the effect of physiological factors on the EEG signal. The algorithm proposed in this study utilizes an attention mechanism to allocate channel weights (AMACW). The model gets the correlation among channels by learning from good channel data. Interpolation assigns weights based on learned correlations without the need for electrode location information, solving the difficulty that traditional methods cannot interpolate bad channels at unknown locations. To avoid an overly concentrated weight distribution of the model when generating data, we designed the channel masking (CM). This method spreads attention and allows the model to utilize data from multiple channels. We evaluate the reconstruction performance of the model using EEG data with 1 to 5 bad channels. With EEGLAB’s interpolation method as a performance reference, tests have shown that the AMACW models can effectively reconstruct bad channels.

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Section: Discussionsupporting

confidence: 68%

“… Bahador et al (2021) proposed an interpolation method that consists of two steps. (1) The data is sliced into smaller segments in the temporal dimension and each segment is interpolated using good channel data.…”

Section: Related Researchmentioning

confidence: 99%

Assigning channel weights using an attention mechanism: an EEG interpolation algorithm

Liu,

Wang,

Qiu

et al. 2023

Front. Neurosci.

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“…Inter-channel interpolation When a channel in an array is impacted locally by an artefact, that segment can be replaced using the average or other methods that take into consideration the surrounding channels, which isn’t possible in a single channel approach [ 4 ].…”

Section: Related Workmentioning

confidence: 99%

Channel-independent recreation of artefactual signals in chronically recorded local field potentials using machine learning

2022

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Acquisition of neuronal signals involves a wide range of devices with specific electrical properties. Combined with other physiological sources within the body, the signals sensed by the devices are often distorted. Sometimes these distortions are visually identifiable, other times, they overlay with the signal characteristics making them very difficult to detect. To remove these distortions, the recordings are visually inspected and manually processed. However, this manual annotation process is time-consuming and automatic computational methods are needed to identify and remove these artefacts. Most of the existing artefact removal approaches rely on additional information from other recorded channels and fail when global artefacts are present or the affected channels constitute the majority of the recording system. Addressing this issue, this paper reports a novel channel-independent machine learning model to accurately identify and replace the artefactual segments present in the signals. Discarding these artifactual segments by the existing approaches causes discontinuities in the reproduced signals which may introduce errors in subsequent analyses. To avoid this, the proposed method predicts multiple values of the artefactual region using long–short term memory network to recreate the temporal and spectral properties of the recorded signal. The method has been tested on two open-access data sets and incorporated into the open-access SANTIA (SigMate Advanced: a Novel Tool for Identification of Artefacts in Neuronal Signals) toolbox for community use.

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“…For most mathematical models in EEG-based BCI system applying for diagnosis, prediction and treatment, a complete dataset is imperative. Unfortunately, the real-world data from non-invasive EEG signals can be missing during the data acquisition process due to manual mistakes, hardware failure or software failure [16][17][18][19][20]. More worrisome, the phenomenon of missing observations dramatically causes inaccurate results that would lead to an unreliable diagnosis, or even a reduction in the performance of methodologies.…”

Section: Introductionmentioning

confidence: 99%

“…Performing missing data imputation on non-invasive EEG time series data has become a fundamental step before prosing further usage. Unlike most existing studies solves missing observations which have only considered original flat-view matrix or vector models [17], [20][21][22][23], the paper focus here is to deal with occlusion in tensorial structures without destroying inherent multiway nature of the EEG data. Ideally, the paper proposes a comprehensive model for tensor completion of EEG-based BCIs system by decoding the three main properties of brain signals, namely noise, temporal dynamics, and tensor representation simultaneously.…”

Section: Introductionmentioning

confidence: 99%

iTa-DFiE: An Innovative Tensor Algebra-Based Detection Framework for Incomplete Noninvasive Electroencephalography

Anh Thi Nguyen,

Tao,

Yang

et al. 2024

IEEE Access

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The paper presents a novel recognition framework for incomplete noninvasive Electroencephalography (EEG) signals relying on the recent advances in tensor algebra, named as An Innovative Tensor Algebra -based Detection Framework for Incomplete Noninvasive Electroencephalogra-phy (iTa-DFiE). iTa-DFiE is motivated to improve the diagnostic performance by tackling the major problems shared by a variety of noninvasive EEG-based Brain-Computer Interfaces (BCIs) application is tensorial structured time series with occlusions. The aforementioned challenge setting is solved on two major thrusts, including:(1) tensor completion: discovering hidden patterns and learning their evolving trends to offer missing values imputation via improvement of standard Kalman Filter approach; (2) tensor decomposition: extracting essential hidden information from multiaspect data tensor via extending the most well-known tensor factorization Tucker. The effectiveness and efficientness of the proposed tensor-based framework is proved via successfully improving the pattern classification results on two real-world noninvasive EEG-based motor imagery BCI with diverse corrupted data scenarios, especially in occurrence of consecutive missing observations. Strikingly, iTa-DFiE also outperforms the conventional matrices-based methods and the state-of-the-art tensor techniques in terms of missing reconstructions and feature extraction as well.

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Reconstruction of missing channel in electroencephalogram using spatiotemporal correlation-based averaging

Cited by 4 publications

References 45 publications

Assigning channel weights using an attention mechanism: an EEG interpolation algorithm

Assigning channel weights using an attention mechanism: an EEG interpolation algorithm

Channel-independent recreation of artefactual signals in chronically recorded local field potentials using machine learning

iTa-DFiE: An Innovative Tensor Algebra-Based Detection Framework for Incomplete Noninvasive Electroencephalography

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