L. K. Hansen, Sofie Therese Hansen, Carsten Stahlhut
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引用次数: 2
摘要
基于脑电图的人脑功能实时成像在质量控制、在线实验设计、脑状态解码和神经反馈等方面具有广泛的应用前景。在移动应用程序中,这些可能性作为个人状态监测和健康系统的元素具有吸引力,而在临床环境中,患者可能需要在准自然条件下进行成像。在移动实时系统中,与EEG成像问题的病态性相关的挑战不断升级,新算法和元数据的使用可能是成功的必要条件。根据最近的工作(Delorme et al., 2011),我们假设感兴趣的解是稀疏的。我们为时间稀疏解提出了一个新的马尔可夫先验,并通过所谓的“变分绞索”实现了对稀疏解的直接搜索(Kappen, 2011)。我们证明了新的先验和推理方案导致基于“多测量向量”方法的竞争稀疏贝叶斯方案的改进解决方案。
Mobile real-time EEG imaging Bayesian inference with sparse, temporally smooth source priors
EEG based real-time imaging of human brain function has many potential applications including quality control, in-line experimental design, brain state decoding, and neuro-feedback. In mobile applications these possibilities are attractive as elements in systems for personal state monitoring and well-being, and in clinical settings were patients may need imaging under quasi-natural conditions. Challenges related to the ill-posed nature of the EEG imaging problem escalate in mobile real-time systems and new algorithms and the use of meta-data may be necessary to succeed. Based on recent work (Delorme et al., 2011) we hypothesize that solutions of interest are sparse. We propose a new Markovian prior for temporally sparse solutions and a direct search for sparse solutions as implemented by the so-called “variational garrote” (Kappen, 2011). We show that the new prior and inference scheme leads to improved solutions over competing sparse Bayesian schemes based on the “multiple measurement vectors” approach.
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