深度知觉的神经计算。
Neural computations underlying depth perception.
机构信息
Dept. of Brain and Cognitive Sciences, Center for Visual Science, University of Rochester, NY 14627, United States.
出版信息
Curr Opin Neurobiol. 2010 Jun;20(3):367-75. doi: 10.1016/j.conb.2010.04.006. Epub 2010 May 6.
Abstract
Neural mechanisms underlying depth perception are reviewed with respect to three computational goals: determining surface depth order, gauging depth intervals, and representing 3D surface geometry and object shape. Accumulating evidence suggests that these three computational steps correspond to different stages of cortical processing. Early visual areas appear to be involved in depth ordering, while depth intervals, expressed in terms of relative disparities, are likely represented at intermediate stages. Finally, 3D surfaces appear to be processed in higher cortical areas, including an area in which individual neurons encode 3D surface geometry, and a population of these neurons may therefore represent 3D object shape. How these processes are integrated to form a coherent 3D percept of the world remains to be understood.
摘要
本文回顾了深度知觉的神经机制,涉及三个计算目标:确定表面深度顺序、测量深度间隔以及表示 3D 表面几何形状和物体形状。越来越多的证据表明,这三个计算步骤对应于皮层处理的不同阶段。早期视觉区域似乎参与了深度排序,而深度间隔(以相对视差表示)可能在中间阶段表示。最后,3D 表面似乎在更高的皮层区域中进行处理,包括一个个体神经元编码 3D 表面几何形状的区域,因此这些神经元的一部分可能代表 3D 物体形状。这些过程如何整合形成对世界的连贯 3D 感知仍有待理解。
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