Add to ORKGWe study a novel architecture and training procedure for locomotion tasks. A high-frequency, low-level “spinal” network with access to proprioceptive sensors learns sensorimotor primitives by training on simple tasks. This pre-trained module is fixed and connected to a low-frequency, high-level “cortical” network, with access to all sensors, which drives behavior by modulating the inputs to the spinal network. Where a monolithic end-to-end architecture fails completely, learning with a pre-trained spinal module succeeds at multiple high-level tasks, and enables the effective exploration required to learn from sparse rewards. We test our proposed architecture on three simulated bodies: a 16-dimensional swimming snake, a 20-dimensional quadru...
Each human lower-limb contains over 50 muscles that are coordinated during locomotion. It has been h...
Compliant robots can be more versatile than traditional robots, but theircontrol is more complex. Th...
Motor control systems in the brain of humans and mammals are hierarchically organised, with each lev...
This thesis studies the broad problem of learning robust control policies for difficult physics-base...
Animals show remarkable rich motion skills which are still far from realizable with robots. Inspired...
In the mammalian nervous system, the sensorimotor interface between cortex and spinal cord plays a k...
Producing locomotion controllers for general bodies has multiple applications, foremost in robotics....
In this letter, we present a method for integrating central pattern generators (CPGs), i.e. systems ...
Human locomotion requires a complex interplay of the mechanical, sensor, neural and motor systems of...
The ability to form support contacts at discontinuous locations makes legged robots suitable for loc...
The control of human locomotion engages various brain structures and numerous muscles. Even though t...
Motor control systems in the brain humans and mammals are hierarchically organised, with each level ...
The neural control of human locomotion is not fully understood. As current experimental techniques p...
This paper describes a neural learning architecture for control of legged robots inspired by mammali...
Human walking is a dynamic, partly self-stabilizing process relying on the interaction of the biomec...
Each human lower-limb contains over 50 muscles that are coordinated during locomotion. It has been h...
Compliant robots can be more versatile than traditional robots, but theircontrol is more complex. Th...
Motor control systems in the brain of humans and mammals are hierarchically organised, with each lev...
This thesis studies the broad problem of learning robust control policies for difficult physics-base...
Animals show remarkable rich motion skills which are still far from realizable with robots. Inspired...
In the mammalian nervous system, the sensorimotor interface between cortex and spinal cord plays a k...
Producing locomotion controllers for general bodies has multiple applications, foremost in robotics....
In this letter, we present a method for integrating central pattern generators (CPGs), i.e. systems ...
Human locomotion requires a complex interplay of the mechanical, sensor, neural and motor systems of...
The ability to form support contacts at discontinuous locations makes legged robots suitable for loc...
The control of human locomotion engages various brain structures and numerous muscles. Even though t...
Motor control systems in the brain humans and mammals are hierarchically organised, with each level ...
The neural control of human locomotion is not fully understood. As current experimental techniques p...
This paper describes a neural learning architecture for control of legged robots inspired by mammali...
Human walking is a dynamic, partly self-stabilizing process relying on the interaction of the biomec...
Each human lower-limb contains over 50 muscles that are coordinated during locomotion. It has been h...
Compliant robots can be more versatile than traditional robots, but theircontrol is more complex. Th...
Motor control systems in the brain of humans and mammals are hierarchically organised, with each lev...