快速大脑的皮质柱

R. Stoop, Victor Saase, C. Wagner, Britta Stoop, R. Stoop
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引用次数: 3

摘要

人们普遍认为,在皮质柱中观察到的特殊线路增强了神经计算能力。我们使用神经网络重新布线执行现实世界的认知任务来研究这一论点的有效性。然而,在对纵队内部线路的大规模调查中,我们没有发现上述效应的痕迹。正是在介观的柱间尺度上,柱的存在——很大程度上与它们的内部组织无关——提高了信息传输的速度,并最小化了将分布式柱计算绑定到时空相干结果所需的总布线长度。
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Cortical columns for quick brains
It is widely believed that the particular wiring observed within cortical columns boosts neural computation. We use rewiring of neural networks performing real-world cognitive tasks to study the validity of this argument. In a vast survey of wirings within the column we detect, however, no traces of the proposed effect. It is on the mesoscopic inter-columnar scale that the existence of columns - largely irrespective of their inner organization - enhances the speed of information transfer and minimizes the total wiring length required to bind the distributed columnar computations towards spatio-temporally coherent results.
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