Reaching for objects and grasping them is a fundamental skill for any autonomous robot that interacts with its environment. Although this skill seems trivial to adults, who effortlessly pick up even objects they have never seen before, it is hard for other animals, for human infants, and for most autonomous robots. Any time during movement preparation and execution, human reaching movement are updated if the visual scene changes (with a delay of about 100 ms). The capability for online updating highlights how tightly perception, movement planning, and movement generation are integrated in humans. Here, we report on an effort to reproduce this tight integration in a neural dynamic process model of reaching and grasping that covers the comple...
Abstract. The sensorimotor maps link the perceived states to actions, required to achieve the goals ...
With the recent advent of neuromorphic hardware there has been a corresponding rise in interest in s...
In this paper we show how a simulated anthropomorphic robotic arm controlled by an artificial neural...
Abstract — We present a neuro-dynamic model of looking, reaching, and grasping movements in infants ...
Neurally inspired robotics already has a long history that includes reactive systems emulating refle...
We present an architecture based on the Dynamic Field Theory for the problem of scene representation...
This tutorial presents an architecture for autonomous robots to generate behavior in joint action ta...
Abstract—Based on the concepts of dynamic field theory (DFT), we present an architecture that autono...
In this article, we present a neurobiologically inspired multinetwork architecture based on knowledg...
We investigated how the CNS learns to control movements in different dynamical conditions, and how t...
This tutorial presents an architecture for autonomous robots to generate behavior in joint action ta...
The works reported in this thesis focus upon synthesising neural controllers for anthropomorphic rob...
Abstract. Looking is one of the most basic and fundamental goal-directed behaviors. The neural circu...
Neurally inspired robotics already has a long history that includes reactive systems emulating refle...
Abstract — We present an attractor based dynamics that au-tonomously generates temporally discrete m...
Abstract. The sensorimotor maps link the perceived states to actions, required to achieve the goals ...
With the recent advent of neuromorphic hardware there has been a corresponding rise in interest in s...
In this paper we show how a simulated anthropomorphic robotic arm controlled by an artificial neural...
Abstract — We present a neuro-dynamic model of looking, reaching, and grasping movements in infants ...
Neurally inspired robotics already has a long history that includes reactive systems emulating refle...
We present an architecture based on the Dynamic Field Theory for the problem of scene representation...
This tutorial presents an architecture for autonomous robots to generate behavior in joint action ta...
Abstract—Based on the concepts of dynamic field theory (DFT), we present an architecture that autono...
In this article, we present a neurobiologically inspired multinetwork architecture based on knowledg...
We investigated how the CNS learns to control movements in different dynamical conditions, and how t...
This tutorial presents an architecture for autonomous robots to generate behavior in joint action ta...
The works reported in this thesis focus upon synthesising neural controllers for anthropomorphic rob...
Abstract. Looking is one of the most basic and fundamental goal-directed behaviors. The neural circu...
Neurally inspired robotics already has a long history that includes reactive systems emulating refle...
Abstract — We present an attractor based dynamics that au-tonomously generates temporally discrete m...
Abstract. The sensorimotor maps link the perceived states to actions, required to achieve the goals ...
With the recent advent of neuromorphic hardware there has been a corresponding rise in interest in s...
In this paper we show how a simulated anthropomorphic robotic arm controlled by an artificial neural...