The adaptation properties of a compartment system

Proceedings II Workshop on Cybernetic Vision Pub Date : 1996-12-09 DOI:10.1109/CYBVIS.1996.629435

J. Raynauld

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Abstract

The fact that our senses adapt is one of the most important characteristics of our sensory system. Since ambient light varies over such a large dynamic range, adaptation is an important aspect of vision in all species. In the vertebrate retina, Weber-Fechner adaptation can be observed at the level of the photoreceptor itself. Using the ergodicity theorem from statistical mechanics, it has been possible to analyze the adaptation properties of the compartment model of Lamb et al. (1981) and to predict the value of Io, the background intensity at which the sensitivity is reduced by one-half. It is simply equal to N, the number of compartments in the outer segment of rod and cones, divided by T, the time constant of biochemical process limiting the recovery of the response. For the cones, the number of compartments is set equal to the number of folds (disks) in the outer segment, for the rods, an empirical rule has been found. The decay of the photocurrent after a small flash has been used to estimate the time constant of the limiting process. The predictions for Io of rods and cones are generally in good agreement with experimental values obtained over the years.

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隔室系统的自适应特性

我们的感官适应是我们感觉系统最重要的特征之一。由于环境光在如此大的动态范围内变化，适应是所有物种视觉的一个重要方面。在脊椎动物视网膜中，可以在感光器本身的水平上观察到韦伯-费希纳适应。利用统计力学中的遍历性定理，可以分析Lamb等人(1981)的隔室模型的自适应特性，并预测灵敏度降低一半的背景强度Io的值。它简单地等于N，杆状细胞和锥状细胞外段的隔室数，除以T，生化过程限制反应恢复的时间常数。对于锥细胞，隔室的数量等于外层部分的折叠(圆盘)的数量，对于杆细胞，已经发现了一个经验规律。利用小闪后光电流的衰减来估计极限过程的时间常数。对视杆细胞和视锥细胞Io的预测通常与多年来获得的实验值吻合得很好。

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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Proceedings II Workshop on Cybernetic Vision

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