Add to ORKGHumans have exceptional abilities to learn new skills, manipulate tools and objects, and interact with our environment. In order to be successful at these tasks, our brain has developed learning mechanisms to deal with and compensate for the constantly changing dynamics of the world. If this mechanism or mechanisms can be understood from a computational point of view, then they can also be used to drive the adaptability and learning of robots. In this paper, we will present a new technique for examining changes in the feedforward motor command due to adaptation. This technique can then be utilized for examining motor adaptation in humans and determining a computational algorithm which explains motor learning. © 2007
The plasticity of the living matter of our nervous system, in short, is the reason why we do a thing...
Humans exploit dynamics—gravity, inertia, joint coupling, elasticity, and so on—as a regular part of...
Whenever we perform a movement and interact with objects in our environment, our central nervous sy...
A remarkable characteristic of our motor system is its enormous capacity for change, manifest in our...
We investigated how the CNS learns to control movements in different dynamical conditions, and how t...
Whenever we perform a movement and interact with objects in our environment, our central nervous sys...
2015-07-10In this dissertation study, I conducted behavioral experiment and applied computational th...
Humans can interact with their environment by tuning the properties of the musculoskeletal system to...
Motor adaptation is a form of learning in which the execution of movements is adjusted in a predict...
Humans can interact with their environment by tuning the properties of the musculoskeletal system to...
Based on computational principles, the concept of an internal model for adaptive control has been di...
Humans and other animals adapt motor commands to predictable disturbances within tens of trials in l...
University of Minnesota Ph.D. dissertation. November 2008. Major: Biomedical Engineering. Advisor: P...
The topic of human movement, and the question of how humans learn new behaviors, has puzzled philoso...
Abstract When humans are exposed to external forces while performing arm movements, they adapt by co...
The plasticity of the living matter of our nervous system, in short, is the reason why we do a thing...
Humans exploit dynamics—gravity, inertia, joint coupling, elasticity, and so on—as a regular part of...
Whenever we perform a movement and interact with objects in our environment, our central nervous sy...
A remarkable characteristic of our motor system is its enormous capacity for change, manifest in our...
We investigated how the CNS learns to control movements in different dynamical conditions, and how t...
Whenever we perform a movement and interact with objects in our environment, our central nervous sys...
2015-07-10In this dissertation study, I conducted behavioral experiment and applied computational th...
Humans can interact with their environment by tuning the properties of the musculoskeletal system to...
Motor adaptation is a form of learning in which the execution of movements is adjusted in a predict...
Humans can interact with their environment by tuning the properties of the musculoskeletal system to...
Based on computational principles, the concept of an internal model for adaptive control has been di...
Humans and other animals adapt motor commands to predictable disturbances within tens of trials in l...
University of Minnesota Ph.D. dissertation. November 2008. Major: Biomedical Engineering. Advisor: P...
The topic of human movement, and the question of how humans learn new behaviors, has puzzled philoso...
Abstract When humans are exposed to external forces while performing arm movements, they adapt by co...
The plasticity of the living matter of our nervous system, in short, is the reason why we do a thing...
Humans exploit dynamics—gravity, inertia, joint coupling, elasticity, and so on—as a regular part of...
Whenever we perform a movement and interact with objects in our environment, our central nervous sy...