The emergence of temporal hyperacuity from widely tuned cell populations.

Network (Bristol, England) Pub Date : 2004-08-01

Janine M Wotton, Michael J Ferragamo, Mark I Sanderson

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Abstract

Typically, individual neural cells operate on a millisecond time scale yet behaviorally animals reveal sub-microsecond acuity. Our model resolves this huge discrepancy by using populations of many widely tuned cells to attain sub-microsecond resolution in a temporal discrimination task. An echolocating bat uses its auditory system to locate objects and it demonstrates remarkable temporal precision in psychophysical tasks. Auditory cells were simulated using realistic parameters and connected in three ascending layers with descending projections from auditory cortex. Coincidence detection of firing collicular cells at thalamus and subsequent integration of multiple inputs at cortex, produce an estimate of time represented as the mean of the active cortical population. Multiple estimates allow the model bat to use memory to recognize predictable change in stimuli values. The best performance is produced using cortical feedback and a computation of target time based on combining the current and previous estimates. Temporal hyperacuity is attained through population coding of physiologically realistic cells but depends on the inherent properties of the psychophysical task.

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从广泛调谐的细胞群中出现的时间超敏锐度。

一般来说，单个神经细胞在毫秒级的时间尺度上运作，而行为动物显示出亚微秒级的敏锐度。我们的模型通过使用许多广泛调谐的细胞群体来解决这种巨大的差异，从而在时间识别任务中获得亚微秒分辨率。回声定位蝙蝠利用听觉系统来定位物体，它在心理物理任务中表现出非凡的时间精确性。用真实参数模拟听觉细胞，并通过听觉皮层的下降投影将听觉细胞连接成三个上升层。对丘脑丘状细胞放电的巧合检测和随后对皮层多个输入的整合，产生了一个时间估计，表示为活跃皮层群的平均值。多重估计允许模型蝙蝠使用记忆来识别刺激值的可预测变化。使用皮质反馈和基于当前和先前估计的目标时间计算产生最佳性能。时间超敏是通过生理现实细胞的群体编码实现的，但取决于心理物理任务的固有特性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Network (Bristol, England)

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