AbstractA physiologically based neural network model was constructed to study cortical motion processing during pursuit eye movements. The model consists of three layers of computational units, simulating information processing by direction selective neurons in the primary visual cortex (V1), motion selective neurons in the middle-temporal area, and pursuit selective neurons in the middle-superior-temporal (MST) area. MST units integrate visual and eye-movement related information, and their connections develop during an unsupervised training process. The resulting MST units represent a transition from retinal to real-world reference frame. By analyzing the model connectivity, mechanisms underlying the functions performed by the network are...
Neurons in the dorsal pathway of the visual cortex are thought to be involved in motion processing. ...
The visual cortex analyzes motion information along hierarchically arranged visual areas that intera...
In this paper we present a bio-inspired connectionist model for visual perception of motion and its ...
Cells in the dorsal medial superior temporal cortex (MSTd) process optic flow generated by self-moti...
Smooth pursuit eye movements are eye rotations that are used to maintain fixation on a moving target...
Animals use vision to traverse novel cluttered environments with apparent ease. Evidence suggests th...
AbstractDuring pursuit of a circularly moving target, the perceived movement of a second circularly ...
A simple and biologically plausible model is proposed to simulate the optic flow computation taking ...
For the successful estimation of self-motion based on visual cues it is necessary to take self-induc...
Humans can easily understand other people’s actions through visual systems, while com-puters cannot....
<div><p>Humans can easily understand other people’s actions through visual systems, while computers ...
Humans can easily understand other people's actions through visual systems, while computers cannot. ...
For self-driving vehicles, aerial drones, and autonomous robots to be successfully deployed in the r...
A model is proposed to demonstrate how neurons in the primary visual cortex could self-organize to r...
Neural activity in the frontal eye fields controls smooth pursuit eye movements, but the relationshi...
Neurons in the dorsal pathway of the visual cortex are thought to be involved in motion processing. ...
The visual cortex analyzes motion information along hierarchically arranged visual areas that intera...
In this paper we present a bio-inspired connectionist model for visual perception of motion and its ...
Cells in the dorsal medial superior temporal cortex (MSTd) process optic flow generated by self-moti...
Smooth pursuit eye movements are eye rotations that are used to maintain fixation on a moving target...
Animals use vision to traverse novel cluttered environments with apparent ease. Evidence suggests th...
AbstractDuring pursuit of a circularly moving target, the perceived movement of a second circularly ...
A simple and biologically plausible model is proposed to simulate the optic flow computation taking ...
For the successful estimation of self-motion based on visual cues it is necessary to take self-induc...
Humans can easily understand other people’s actions through visual systems, while com-puters cannot....
<div><p>Humans can easily understand other people’s actions through visual systems, while computers ...
Humans can easily understand other people's actions through visual systems, while computers cannot. ...
For self-driving vehicles, aerial drones, and autonomous robots to be successfully deployed in the r...
A model is proposed to demonstrate how neurons in the primary visual cortex could self-organize to r...
Neural activity in the frontal eye fields controls smooth pursuit eye movements, but the relationshi...
Neurons in the dorsal pathway of the visual cortex are thought to be involved in motion processing. ...
The visual cortex analyzes motion information along hierarchically arranged visual areas that intera...
In this paper we present a bio-inspired connectionist model for visual perception of motion and its ...