How Quadrupeds Benefit from Lower Leg Passive Elasticity
2020
Poster
dlg
Recently developed and fully actuated, legged robots start showing exciting locomotion capabilities, but rely heavily on high-power actuators, high-frequency sensors, and complex locomotion controllers. The engineering solutions implemented in these legged robots are much different compared to animals. Vertebrate animals share magnitudes slower neurocontrol signal velocities [1] compared to their robot counterparts. Also, animals feature a plethora of cascaded and underactuated passive elastic structures [2].
Author(s): | Felix Ruppert and Alexander Badri-Spröwitz |
Year: | 2020 |
Month: | May |
Department(s): | Dynamische Lokomotion |
Research Project(s): |
Animal-inspired robot legs
|
Bibtex Type: | Poster (poster) |
Paper Type: | Conference |
Digital: | True |
Event Name: | Dynamic Walking |
Event Place: | USA |
URL: | https://www.seas.upenn.edu/~posa/DynamicWalking2020/643-944-1-RV.pdf |
Attachments: |
Abstract
Poster |
BibTex @poster{ruppert2020b, title = {How Quadrupeds Benefit from Lower Leg Passive Elasticity}, author = {Ruppert, Felix and Badri-Spr{\"o}witz, Alexander}, month = may, year = {2020}, doi = {}, url = {https://www.seas.upenn.edu/~posa/DynamicWalking2020/643-944-1-RV.pdf}, month_numeric = {5} } |