The optimal synapse for sparse, binary signals in the rod pathway: Neural Computation

Paul T Clark; Mark C W van Rossum

doi:10.1162/089976606774841530

The optimal synapse for sparse, binary signals in the rod pathway: Neural Computation

Paul T Clark, Mark C W van Rossum

Research output: Contribution to journal › Article › peer-review

Abstract

The sparsity of photons at very low light levels necessitates a nonlinear synaptic transfer function between the rod photoreceptors and the rod-bipolar cells. We examine different ways to characterize the performance of the pathway: the error rate, two variants of the mutual information, and the signal-to-noise ratio. Simulation of the pathway shows that these approaches yield substantially different performance at very low light levels and that maximizing the signal-to-noise ratio yields the best performance when judged from simulated images. The results are compared to recent data.

Original language	English
Pages (from-to)	26-44
Number of pages	19
Journal	Neural Computation
Volume	18
Issue number	1
DOIs	https://doi.org/10.1162/089976606774841530
Publication status	Published - Jan 2006

Keywords

Animals
Contrast Sensitivity
Dark Adaptation
Humans
Light
Models, Neurological
Neural Networks (Computer)
Photic Stimulation
Photons
Retinal Bipolar Cells
Retinal Rod Photoreceptor Cells
Sensory Thresholds
Synapses
Synaptic Transmission
Vision, Ocular
Visual Pathways

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title = "The optimal synapse for sparse, binary signals in the rod pathway: Neural Computation",

abstract = "The sparsity of photons at very low light levels necessitates a nonlinear synaptic transfer function between the rod photoreceptors and the rod-bipolar cells. We examine different ways to characterize the performance of the pathway: the error rate, two variants of the mutual information, and the signal-to-noise ratio. Simulation of the pathway shows that these approaches yield substantially different performance at very low light levels and that maximizing the signal-to-noise ratio yields the best performance when judged from simulated images. The results are compared to recent data.",

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AB - The sparsity of photons at very low light levels necessitates a nonlinear synaptic transfer function between the rod photoreceptors and the rod-bipolar cells. We examine different ways to characterize the performance of the pathway: the error rate, two variants of the mutual information, and the signal-to-noise ratio. Simulation of the pathway shows that these approaches yield substantially different performance at very low light levels and that maximizing the signal-to-noise ratio yields the best performance when judged from simulated images. The results are compared to recent data.

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KW - Contrast Sensitivity

KW - Dark Adaptation

KW - Humans

KW - Light

KW - Models, Neurological

KW - Neural Networks (Computer)

KW - Photic Stimulation

KW - Photons

KW - Retinal Bipolar Cells

KW - Retinal Rod Photoreceptor Cells

KW - Sensory Thresholds

KW - Synapses

KW - Synaptic Transmission

KW - Vision, Ocular

KW - Visual Pathways

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JO - Neural Computation

JF - Neural Computation

SN - 0899-7667

IS - 1

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The optimal synapse for sparse, binary signals in the rod pathway: Neural Computation

Abstract

Keywords

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