This paper describes a self-organizing neural network architecture that transforms optic now information into representations of heading, scene depth, and moving object locations. These representations are used to reactively navigate in simulations involving obstacle avoidance and pursuit of a moving target. The network's weights are trained during an action-perception cycle in which self-generated eye and body movements produce optic flow information, thus allowing the network to tunc itself without requiring explicit knowledge of sensor geometry. The confounding effect of eye movement during translation is suppressed by learning the relationship between eye movement outflow commands and the optic flow signals that they induce. The remaini...
Robotic navigation has been an area of intense research since the onset of mobile robot development....
Optical flow (OF) is a powerful motion cue that captures the fusion of two important properties for ...
How to transform a mixed flow of sensory and motor information into memory state of self-location an...
This paper describes a self-organizing neural network architecture that transforms optic now informa...
Most algorithms for steering, obstacle avoidance, and moving object detection rely on accurate self-...
A neural model is developed to explain how humans can approach a goal object on foot while steering ...
In this paper, the authors present information processing strategies, derived from neurobiology, whi...
International audienceWe developed a Spiking Neural Network composed of two layers that processes ev...
Interest in the processing of optic flow has increased recently in both the neurophysiological and t...
AbstractA physiologically based neural network model was constructed to study cortical motion proces...
Animals avoid obstacles and approach goals in novel cluttered environments using visual information,...
Cells in the dorsal medial superior temporal cortex (MSTd) process optic flow generated by self-moti...
We propose a biologically plausible neural network for trajectory formation and obstacle avoidance. ...
For self-driving vehicles, aerial drones, and autonomous robots to be successfully deployed in the r...
This paper describes a self-organizing neural network that rapidly learns a body-centered representa...
Robotic navigation has been an area of intense research since the onset of mobile robot development....
Optical flow (OF) is a powerful motion cue that captures the fusion of two important properties for ...
How to transform a mixed flow of sensory and motor information into memory state of self-location an...
This paper describes a self-organizing neural network architecture that transforms optic now informa...
Most algorithms for steering, obstacle avoidance, and moving object detection rely on accurate self-...
A neural model is developed to explain how humans can approach a goal object on foot while steering ...
In this paper, the authors present information processing strategies, derived from neurobiology, whi...
International audienceWe developed a Spiking Neural Network composed of two layers that processes ev...
Interest in the processing of optic flow has increased recently in both the neurophysiological and t...
AbstractA physiologically based neural network model was constructed to study cortical motion proces...
Animals avoid obstacles and approach goals in novel cluttered environments using visual information,...
Cells in the dorsal medial superior temporal cortex (MSTd) process optic flow generated by self-moti...
We propose a biologically plausible neural network for trajectory formation and obstacle avoidance. ...
For self-driving vehicles, aerial drones, and autonomous robots to be successfully deployed in the r...
This paper describes a self-organizing neural network that rapidly learns a body-centered representa...
Robotic navigation has been an area of intense research since the onset of mobile robot development....
Optical flow (OF) is a powerful motion cue that captures the fusion of two important properties for ...
How to transform a mixed flow of sensory and motor information into memory state of self-location an...