<div><p>The developing visual system of many mammalian species is partially structured and organized even before the onset of vision. Spontaneous neural activity, which spreads in waves across the retina, has been suggested to play a major role in these prenatal structuring processes. Recently, it has been shown that when employing an efficient coding strategy, such as sparse coding, these retinal activity patterns lead to basis functions that resemble optimal stimuli of simple cells in primary visual cortex (V1). Here we present the results of applying a coding strategy that optimizes for temporal slowness, namely Slow Feature Analysis (SFA), to a biologically plausible model of retinal waves. Previously, SFA has been successfully applied ...
The development of neural circuits is perhaps one of the most fascinating phenomena of nature. Neura...
Following earlier studies which showed that a sparse coding principle may explain the receptive fiel...
A neural model is described of how spontaneous retinal waves are formed in infant mammals, and how t...
The developing visual system of many mammalian species is partially structured and organized even be...
A long standing question of biological vision research is to identify the computational goal underly...
In this study, we investigate temporal slowness as a learning principle for receptive fields using s...
We apply Slow Feature Analysis (SFA) to image sequences generated from natural images using a range ...
The intricate patterning and complex circuitry of the nervous system beg the question of how such pr...
We develop a group-theoretical analysis of slow feature analysis for the case where the input data a...
<div><p>Following earlier studies which showed that a sparse coding principle may explain the recept...
The appearance of objects in an image can change dramatically depending on their pose, distance, and...
Slow Feature Analysis (SFA) is an efficient algorithm for learning input-output functions that extra...
Following earlier studies which showed that a sparse coding principle may explain the receptive fiel...
Natural vision is a highly dynamic process. Frequent body, head, and eye movements constantly bring ...
Our goal is to understand the dynamics of neural computations in low-level vision. We study how the ...
The development of neural circuits is perhaps one of the most fascinating phenomena of nature. Neura...
Following earlier studies which showed that a sparse coding principle may explain the receptive fiel...
A neural model is described of how spontaneous retinal waves are formed in infant mammals, and how t...
The developing visual system of many mammalian species is partially structured and organized even be...
A long standing question of biological vision research is to identify the computational goal underly...
In this study, we investigate temporal slowness as a learning principle for receptive fields using s...
We apply Slow Feature Analysis (SFA) to image sequences generated from natural images using a range ...
The intricate patterning and complex circuitry of the nervous system beg the question of how such pr...
We develop a group-theoretical analysis of slow feature analysis for the case where the input data a...
<div><p>Following earlier studies which showed that a sparse coding principle may explain the recept...
The appearance of objects in an image can change dramatically depending on their pose, distance, and...
Slow Feature Analysis (SFA) is an efficient algorithm for learning input-output functions that extra...
Following earlier studies which showed that a sparse coding principle may explain the receptive fiel...
Natural vision is a highly dynamic process. Frequent body, head, and eye movements constantly bring ...
Our goal is to understand the dynamics of neural computations in low-level vision. We study how the ...
The development of neural circuits is perhaps one of the most fascinating phenomena of nature. Neura...
Following earlier studies which showed that a sparse coding principle may explain the receptive fiel...
A neural model is described of how spontaneous retinal waves are formed in infant mammals, and how t...