TY - GEN
T1 - Rigid vs. elastic actuation
T2 - 25th IEEE/RSJ International Conference on Robotics and Intelligent Systems, IROS 2012
AU - Haddadin, Sami
AU - Mansfeld, Nico
AU - Albu-Schffer, Alin
PY - 2012
Y1 - 2012
N2 - Intrinsically elastic joints have become increasingly popular over the last years. Commonly, they are considered to outperform rigid actuation in terms of peak dynamics, robustness, and energy efficiency. In particular, the possible increase of link speed by adequate motor excitation trajectories, such that the elastic transmission temporarily stores elastic energy and then timely converts it into kinetic link energy, is a new control problem in robotics. However, despite being a popular argument in favor of elastic actuation, it was not shown yet that this potential speed gain is truly inherent to the physical properties of the mechanism. In order to argue that 'elasticity is superior to input torque', i.e. size and weight, it still needs to be derived that this new feature does not come at the cost of increasing weight for a given actuation technology. Therefore, we analyze, under which circumstances 'extracting' a certain amount of mass from a rigid joint and 'investing' this into an elastic mechanism in the drive train leads to such a performance increase. For this, we derive the general scaling behavior of rigid joints and compare their capabilities in terms of maximum velocity to the performance behavior of an elastic joint, while taking into consideration the most important real-world constraints.
AB - Intrinsically elastic joints have become increasingly popular over the last years. Commonly, they are considered to outperform rigid actuation in terms of peak dynamics, robustness, and energy efficiency. In particular, the possible increase of link speed by adequate motor excitation trajectories, such that the elastic transmission temporarily stores elastic energy and then timely converts it into kinetic link energy, is a new control problem in robotics. However, despite being a popular argument in favor of elastic actuation, it was not shown yet that this potential speed gain is truly inherent to the physical properties of the mechanism. In order to argue that 'elasticity is superior to input torque', i.e. size and weight, it still needs to be derived that this new feature does not come at the cost of increasing weight for a given actuation technology. Therefore, we analyze, under which circumstances 'extracting' a certain amount of mass from a rigid joint and 'investing' this into an elastic mechanism in the drive train leads to such a performance increase. For this, we derive the general scaling behavior of rigid joints and compare their capabilities in terms of maximum velocity to the performance behavior of an elastic joint, while taking into consideration the most important real-world constraints.
UR - http://www.scopus.com/inward/record.url?scp=84872324743&partnerID=8YFLogxK
U2 - 10.1109/IROS.2012.6386227
DO - 10.1109/IROS.2012.6386227
M3 - Conference contribution
AN - SCOPUS:84872324743
SN - 9781467317375
T3 - IEEE International Conference on Intelligent Robots and Systems
SP - 5097
EP - 5104
BT - 2012 IEEE/RSJ International Conference on Intelligent Robots and Systems, IROS 2012
Y2 - 7 October 2012 through 12 October 2012
ER -