R. Van Ham, B. Vanderborght, M. Van Damme, B. Verrelst and D. Lefeber (2006). "MACCEPA: the mechanically adjustable compliance and controllable equilibrium position actuator for 'controlled passive walking': Difference between revisions
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=Summary= | =Summary= | ||
==Main idea== | ==Main idea== | ||
Robots can be stiff and rigid, but that is not the only option that one has when creating a robot. In order to make robots move more human-like, a mechanism is introduced where actuators with "adaptive compliance" are created tested: *“Nowadays, more and more research groups working on bipeds have started to believe that natural biped walking is a combination of both approaches, requiring actuators with adaptable compliance (inverse of stiffness), resulting in energy efficient walking at different speeds.” | Robots can be stiff and rigid, but that is not the only option that one has when creating a robot. In order to make robots move more human-like, a mechanism is introduced where actuators with "adaptive compliance" are created tested: | ||
*“Nowadays, more and more research groups working on bipeds have started to believe that natural biped walking is a combination of both approaches, requiring actuators with adaptable compliance (inverse of stiffness), resulting in energy efficient walking at different speeds.” |
Revision as of 07:48, 25 February 2021
Summary
Main idea
Robots can be stiff and rigid, but that is not the only option that one has when creating a robot. In order to make robots move more human-like, a mechanism is introduced where actuators with "adaptive compliance" are created tested:
- “Nowadays, more and more research groups working on bipeds have started to believe that natural biped walking is a combination of both approaches, requiring actuators with adaptable compliance (inverse of stiffness), resulting in energy efficient walking at different speeds.”