利用子空间技术估计皮层电发生器的位置

Proceedings of ICASSP '94. IEEE International Conference on Acoustics, Speech and Signal Processing Pub Date : 1994-04-19 DOI:10.1109/ICASSP.1994.389746

D. Klimovski, A. Sergejew, A. Cricenti, G. Egan

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引用次数: 2

摘要

有许多方法应用子空间技术来解决谱估计问题。这些方法是从输入数据构建的协方差矩阵中推导出来的。协方差矩阵可以通过使用适当的矩阵性质和特征分解技术分解成两个子空间。在白噪声和1/f噪声条件下，对三种结合子空间技术的传统到达方向算法的性能进行了评价。选择1/f噪声是因为它是典型的脑电图信号。仿真结果表明，Johnson和DeGraaf(1982)测向算法在两种噪声环境下都表现最好。以典型脑电数据为例，对三种算法的性能进行了评价。Johnson和DeGraaf算法给出的信号方向估计与可能的皮层电发生器的解剖位置大致一致

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Estimation of the position of electrocortical generators via subspace techniques

There are a number of approaches to the application of subspace techniques for solving spectral estimation problems. These approaches are derived from the covariance matrix which is constructed from incoming data. The covariance matrix can be broken down through the use of appropriate matrix properties and eigen-decomposition techniques into two subspaces. The performance of three traditional algorithms which incorporate subspace techniques in direction of arrival are evaluated under both white and 1/f noise conditions. 1/f noise is chosen because it is typical of the EEG signals. Simulation results suggest that the Johnson and DeGraaf (1982) direction finding algorithm performs best under both noise environments. A typical sample of EEG data was used to evaluate the performance of the three algorithms. The Johnson and DeGraaf algorithm gives estimates for the direction of the signal which approximately agree with the anatomical locations of possible electrocortical generators.<>

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Proceedings of ICASSP '94. IEEE International Conference on Acoustics, Speech and Signal Processing

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