TY - JOUR
T1 - Redundancy in Biology and Robotics: Potential of Kinematic Redundancy and its Interplay with Elasticity
AU - Verstraten, Tom
AU - Schumacher, Christian
AU - Furnémont, Raphaël Guy
AU - Seyfarth, André
AU - Beckerle, Philipp
PY - 2020/7
Y1 - 2020/7
N2 - Redundancy facilitates some of the most remarkable capabilities of humans, and is therefore omni-present in our physiology. The relationship between redundancy in robotics and biology is investigated in detail on the Series Elastic Dual-Motor Actuator (SEDMA), an actuator inspired by the kinematic redundancy exhibited by myofibrils. The actuator consists of two motors coupled to a single spring at the output. Such a system has a redundant degree of freedom, which can be exploited to optimize aspects such as accuracy, impedance, fault-tolerance and energy efficiency. To test its potential for human-like motions, the SEDMA actuator is implemented in a hopping robot. Experiments on a physical demonstrator show that the robot’s movement patterns resemble human squat jumps. We conclude that robots with bio-inspired actuator designs facilitate human-like movement, although current technical limitations may prevent them from reaching the same dynamic and energetic performance.
AB - Redundancy facilitates some of the most remarkable capabilities of humans, and is therefore omni-present in our physiology. The relationship between redundancy in robotics and biology is investigated in detail on the Series Elastic Dual-Motor Actuator (SEDMA), an actuator inspired by the kinematic redundancy exhibited by myofibrils. The actuator consists of two motors coupled to a single spring at the output. Such a system has a redundant degree of freedom, which can be exploited to optimize aspects such as accuracy, impedance, fault-tolerance and energy efficiency. To test its potential for human-like motions, the SEDMA actuator is implemented in a hopping robot. Experiments on a physical demonstrator show that the robot’s movement patterns resemble human squat jumps. We conclude that robots with bio-inspired actuator designs facilitate human-like movement, although current technical limitations may prevent them from reaching the same dynamic and energetic performance.
UR - http://www.scopus.com/inward/record.url?scp=85087508974&partnerID=8YFLogxK
U2 - 10.1007/s42235-020-0062-z
DO - 10.1007/s42235-020-0062-z
M3 - Article
VL - 17
SP - 695
EP - 707
JO - Journal of Bionic Engineering
JF - Journal of Bionic Engineering
SN - 1672-6529
IS - 4
ER -