Add to ORKGLike human walking, passive dynamic walking—i.e. walking down a slope with no actuation except gravity—is energy efficient by exploiting the natural dynamics. In the animal world, neural oscillators termed central pattern generators (CPGs) provide the basic rhythm for muscular activity in locomotion. We present a CPG model, which automatically tunes into the resonance frequency of the passive dynamics of a bipedal walker, i.e. the CPG model exhibits resonance tuning behavior. Each leg is coupled to its own CPG, controlling the hip moment of force. Resonance tuning above the endogenous frequency of the CPG—i.e. the CPG’s eigenfrequency—is achieved by feedback of both limb angles to their corresponding CPG, while integration of the limb angle...
The concept of torque-stiffness-controlled dynamic walking expands the applicability of passivity-ba...
Dynamic walking at lower Froude number (Fr) is difficult to realize than that at higher Fr, since bo...
Abstract Two types of neural circuits contribute to legged locomotion: central pattern generators (C...
Like human walking, passive dynamic walking—i.e. walking down a slope with no actuation except gravi...
Humans show great energy efficiency and robustness in rhythmic tasks, such as walking and arm swingi...
Humans show great energy efficiency and robustness in rhythmic tasks, such as walking and arm swingi...
Walking is a very important function of the human movement apparatus. The question how walking is co...
The traditional view of motor control predicates that the central nervous system dictates the motion...
The traditional view of motor control predicates that the central nervous system dictates the motion...
Walking is a very important function of the human movement apparatus. The\ud question how walking is...
Generating biped locomotion patterns is a difficult task because maintaining balance on two legs is ...
International audienceResearch in robot locomotion can be separated into few groups. The dominated r...
International audienceResearch in robot locomotion can be separated into few groups. The dominated r...
Although the concept of central pattern generators (CPGs) controlling locomotion in vertebrates is w...
In this paper, we propose a central pattern generator-based model to control the walking motion of a...
The concept of torque-stiffness-controlled dynamic walking expands the applicability of passivity-ba...
Dynamic walking at lower Froude number (Fr) is difficult to realize than that at higher Fr, since bo...
Abstract Two types of neural circuits contribute to legged locomotion: central pattern generators (C...
Like human walking, passive dynamic walking—i.e. walking down a slope with no actuation except gravi...
Humans show great energy efficiency and robustness in rhythmic tasks, such as walking and arm swingi...
Humans show great energy efficiency and robustness in rhythmic tasks, such as walking and arm swingi...
Walking is a very important function of the human movement apparatus. The question how walking is co...
The traditional view of motor control predicates that the central nervous system dictates the motion...
The traditional view of motor control predicates that the central nervous system dictates the motion...
Walking is a very important function of the human movement apparatus. The\ud question how walking is...
Generating biped locomotion patterns is a difficult task because maintaining balance on two legs is ...
International audienceResearch in robot locomotion can be separated into few groups. The dominated r...
International audienceResearch in robot locomotion can be separated into few groups. The dominated r...
Although the concept of central pattern generators (CPGs) controlling locomotion in vertebrates is w...
In this paper, we propose a central pattern generator-based model to control the walking motion of a...
The concept of torque-stiffness-controlled dynamic walking expands the applicability of passivity-ba...
Dynamic walking at lower Froude number (Fr) is difficult to realize than that at higher Fr, since bo...
Abstract Two types of neural circuits contribute to legged locomotion: central pattern generators (C...