Robust Bayesian estimation of EEG-based brain causality networks
Objective: The multivariate autoregression (MVAR) model is an effective model to construct brain causality networks. However, the accuracy of MVAR parameter estimation is considerably affected by outliers such as head movements and eye blinks contained in EEG signals, especially in short time window...
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sg-ntu-dr.10356-1707092023-09-26T07:02:33Z Robust Bayesian estimation of EEG-based brain causality networks Liu, Ke Lai, Qin Li, Peiyang Yu, Zhuliang Xiao, Bin Guan, Cuntai Wu, Wei School of Computer Science and Engineering Engineering::Computer science and engineering Brain Causal Network Causality Analysis Objective: The multivariate autoregression (MVAR) model is an effective model to construct brain causality networks. However, the accuracy of MVAR parameter estimation is considerably affected by outliers such as head movements and eye blinks contained in EEG signals, especially in short time windows. Methods: We proposed a robust MVAR parameter estimation method based on a Bayesian probabilistic framework and Laplace fitting error known as Lap-SBL. With the Bayesian inference framework, we can accurately estimate the MVAR parameters under short time windows. Additionally, to alleviate the influence of outliers, we model the fitting error using the Laplace distribution instead of the typical Gaussian distribution. We employ convex analysis to model the inference task by approximating the Laplace noise prior with a maximum over Gaussian functions with varying scales. The variational inference approach was used to efficiently estimate the MVAR parameters. Results: The numerical results suggest that the proposed method obtains less parameter estimation bias and more consistent linkages than existing benchmark methods, i.e., LS, LASSO, LAPPS and SBL. The motor imagery experimental data analysis shows that Lap-SBL can better describe the lateralization characteristics of brain network. This lateralization is less apparent in a subject with poor MI classification accuracy. Conclusion and significance: Lap-SBL effectively suppresses the influence of outliers and recovers reliable networks in the presence of outliers and short time windows. This work was supported in part by the National Natural Science Foundation of China under Grants 61703065 and 61876063, in part by the Technology Innovation20302022ZD0211700, and in part by the Natural Science Foundation of Chongqing under Grant CSTB2022NSCQ-MSX0291. 2023-09-26T07:02:33Z 2023-09-26T07:02:33Z 2023 Journal Article Liu, K., Lai, Q., Li, P., Yu, Z., Xiao, B., Guan, C. & Wu, W. (2023). Robust Bayesian estimation of EEG-based brain causality networks. IEEE Transactions On Biomedical Engineering, 70(6), 1879-1890. https://dx.doi.org/10.1109/TBME.2022.3231627 0018-9294 https://hdl.handle.net/10356/170709 10.1109/TBME.2022.3231627 37015386 2-s2.0-85146216825 6 70 1879 1890 en IEEE Transactions on Biomedical Engineering © 2022 IEEE. All rights reserved. |
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Engineering::Computer science and engineering Brain Causal Network Causality Analysis |
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Engineering::Computer science and engineering Brain Causal Network Causality Analysis Liu, Ke Lai, Qin Li, Peiyang Yu, Zhuliang Xiao, Bin Guan, Cuntai Wu, Wei Robust Bayesian estimation of EEG-based brain causality networks |
| description |
Objective: The multivariate autoregression (MVAR) model is an effective model to construct brain causality networks. However, the accuracy of MVAR parameter estimation is considerably affected by outliers such as head movements and eye blinks contained in EEG signals, especially in short time windows. Methods: We proposed a robust MVAR parameter estimation method based on a Bayesian probabilistic framework and Laplace fitting error known as Lap-SBL. With the Bayesian inference framework, we can accurately estimate the MVAR parameters under short time windows. Additionally, to alleviate the influence of outliers, we model the fitting error using the Laplace distribution instead of the typical Gaussian distribution. We employ convex analysis to model the inference task by approximating the Laplace noise prior with a maximum over Gaussian functions with varying scales. The variational inference approach was used to efficiently estimate the MVAR parameters. Results: The numerical results suggest that the proposed method obtains less parameter estimation bias and more consistent linkages than existing benchmark methods, i.e., LS, LASSO, LAPPS and SBL. The motor imagery experimental data analysis shows that Lap-SBL can better describe the lateralization characteristics of brain network. This lateralization is less apparent in a subject with poor MI classification accuracy. Conclusion and significance: Lap-SBL effectively suppresses the influence of outliers and recovers reliable networks in the presence of outliers and short time windows. |
| author2 |
School of Computer Science and Engineering |
| author_facet |
School of Computer Science and Engineering Liu, Ke Lai, Qin Li, Peiyang Yu, Zhuliang Xiao, Bin Guan, Cuntai Wu, Wei |
| format |
Article |
| author |
Liu, Ke Lai, Qin Li, Peiyang Yu, Zhuliang Xiao, Bin Guan, Cuntai Wu, Wei |
| author_sort |
Liu, Ke |
| title |
Robust Bayesian estimation of EEG-based brain causality networks |
| title_short |
Robust Bayesian estimation of EEG-based brain causality networks |
| title_full |
Robust Bayesian estimation of EEG-based brain causality networks |
| title_fullStr |
Robust Bayesian estimation of EEG-based brain causality networks |
| title_full_unstemmed |
Robust Bayesian estimation of EEG-based brain causality networks |
| title_sort |
robust bayesian estimation of eeg-based brain causality networks |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/170709 |
| _version_ |
1779156404454555648 |