Add to ORKGAnimal locomotion patterns are controlled by recurrent neural networks called central pattern generators (CPGs). Although a CPG can oscillate autonomously, its rhythm and phase must be well coordinated with the state of the physical system using sensory inputs. In this paper we propose a learning algorithm for synchronizing neural and physical oscillators with specific phase relationships. Sensory input connections are modified by the correlation between cellular activities and input signals. Simulations show that the learning rule can be used for setting sensory feedback connections to a CPG as well as coupling connections between CPGs
International audienceThis paper presents the use of Rowat and Selverston-type of central pattern ge...
As the engine behind many life phenomena, motor information generated by the central nervous system ...
Rhythmic neural signals serve as basis of many brain processes, in particular of locomotion control ...
This article describes a. neural pattern generator based on a cooperative-competitive feedback neura...
The existence of dedicated neuronal modules such as those organized in the cerebral cortex, thalamus...
The existence of dedicated neuronal modules such as those organized in the cerebral cortex, thalamus...
As an engine of almost all life phenomena, the motor information generated by the central nervous sy...
As an engine of almost all life phenomena, the motor information generated by the central nervous sy...
Animal’s rhythmic movements such as locomotion are considered to be controlled by neural circuits ca...
Neural oscillation is one of the most extensively investigated topics of artificial neural networks....
A learning model for coupled oscillators is proposed. The proposed learning rule takes a simple form...
Neural oscillation is one of the most extensively investigated topics of artificial neural networks....
As an engine of almost all life phenomena, the motor information generated by the central nervous sy...
As an engine of almost all life phenomena, the motor information generated by the central nervous sy...
International audienceThis paper presents the use of Rowat and Selverston-type of central pattern ge...
International audienceThis paper presents the use of Rowat and Selverston-type of central pattern ge...
As the engine behind many life phenomena, motor information generated by the central nervous system ...
Rhythmic neural signals serve as basis of many brain processes, in particular of locomotion control ...
This article describes a. neural pattern generator based on a cooperative-competitive feedback neura...
The existence of dedicated neuronal modules such as those organized in the cerebral cortex, thalamus...
The existence of dedicated neuronal modules such as those organized in the cerebral cortex, thalamus...
As an engine of almost all life phenomena, the motor information generated by the central nervous sy...
As an engine of almost all life phenomena, the motor information generated by the central nervous sy...
Animal’s rhythmic movements such as locomotion are considered to be controlled by neural circuits ca...
Neural oscillation is one of the most extensively investigated topics of artificial neural networks....
A learning model for coupled oscillators is proposed. The proposed learning rule takes a simple form...
Neural oscillation is one of the most extensively investigated topics of artificial neural networks....
As an engine of almost all life phenomena, the motor information generated by the central nervous sy...
As an engine of almost all life phenomena, the motor information generated by the central nervous sy...
International audienceThis paper presents the use of Rowat and Selverston-type of central pattern ge...
International audienceThis paper presents the use of Rowat and Selverston-type of central pattern ge...
As the engine behind many life phenomena, motor information generated by the central nervous system ...
Rhythmic neural signals serve as basis of many brain processes, in particular of locomotion control ...