Robust Sparse Bayesian Learning Based on Minimum Error Entropy for Noisy High-Dimensional Brain Activity Decoding

TL;DR

This paper introduces a robust sparse Bayesian learning framework using minimum error entropy to improve decoding of noisy high-dimensional brain signals, outperforming traditional methods in accuracy and physiological pattern recognition.

Contribution

It proposes a novel MEE-based likelihood function for sparse Bayesian learning, enhancing robustness against noise in high-dimensional brain activity decoding.

Findings

Superior decoding metrics achieved in regression and classification tasks.

Outperforms conventional and state-of-the-art methods.

Enhances robustness in noisy brain signal analysis.

Abstract

Objective: Sparse Bayesian learning provides an effective scheme to solve the high-dimensional problem in brain signal decoding. However, traditional assumptions regarding data distributions such as Gaussian and binomial are potentially inadequate to characterize the noisy signals of brain activity. Hence, this study aims to propose a robust sparse Bayesian learning framework to address noisy highdimensional brain activity decoding. Methods: Motivated by the commendable robustness of the minimum error entropy (MEE) criterion for handling complex data distributions, we proposed an MEE-based likelihood function to facilitate the accurate inference of sparse Bayesian learning in analyzing noisy brain datasets. Results: Our proposed approach was evaluated using two high-dimensional brain decoding tasks in regression and classification contexts, respectively. The experimental results showed that, our approach can realize superior decoding metrics and physiological patterns than the conventional and state-of-the-art methods. Conclusion: Utilizing the proposed MEE-based likelihood model, sparse Bayesian learning is empowered to simultaneously address the challenges of noise and high dimensionality in the brain decoding task. Significance: This work provides a powerful tool to realize robust brain decoding, advancing biomedical engineering applications such as brain-computer interface.