The Human Leg Catapult: Biological Mechanisms for Walking Gait Replicated in the EcoWalker Robot
Humanoid robots and assistive devices have yet to match the efficiency and adaptability of able-bodied human walking in challenging environments. To bridge this performance gap, my projects explored the underlying mechanisms of human locomotion, focusing on the ankle push-off. Ankle push-off has a prominent role in walking due to its high-power output at the end of the stance phase, and due to the impact of its timing on the adaptability to diverse environments. The human leg catapult analogy provides a framework for the projects to understand and replicate the complex biological mechanisms that govern human walking gait. As a platform for the replication, the human-like bipedal EcoWalker robot was developed from version 1 to 3 in three consecutive projects, with iterative design and control updates tailored to each project's goals. Our findings provide insights into the separate roles of mono- and biarticular muscle-tendon units in the human leg catapult, while we also show functional details of the human leg catapult release mechanism through five distinct release processes on the EcoWalker robot. Utilizing the robot in the projects ensures that our findings are relevant to practical applications, allowing humanoid robot and assistive device developers to build on our insights, potentially reducing the performance gap in efficiency and adaptability between able-bodied human walking and artificial walking.
| Author(s): | Bernadett Kiss |
| Year: | 2026 |
| Month: | March |
| BibTeX Type: | Ph.D. Thesis (phdthesis) |
| Address: | Stuttgart, Germany |
| Degree Type: | PhD |
| Note: | Faculty of Civil and Environmental Engineering |
| School: | University of Stuttgart |
| State: | Published |
BibTeX
@phdthesis{Kiss26-PHD-EcoWalker,
title = {The Human Leg Catapult: Biological Mechanisms for Walking Gait Replicated in the Eco{W}alker Robot},
abstract = {Humanoid robots and assistive devices have yet to match the efficiency and adaptability of able-bodied human walking in challenging environments. To bridge this performance gap, my projects explored the underlying mechanisms of human locomotion, focusing on the ankle push-off. Ankle push-off has a prominent role in walking due to its high-power output at the end of the stance phase, and due to the impact of its timing on the adaptability to diverse environments. The human leg catapult analogy provides a framework for the projects to understand and replicate the complex biological mechanisms that govern human walking gait. As a platform for the replication, the human-like bipedal EcoWalker robot was developed from version 1 to 3 in three consecutive projects, with iterative design and control updates tailored to each project's goals. Our findings provide insights into the separate roles of mono- and biarticular muscle-tendon units in the human leg catapult, while we also show functional details of the human leg catapult release mechanism through five distinct release processes on the EcoWalker robot. Utilizing the robot in the projects ensures that our findings are relevant to practical applications, allowing humanoid robot and assistive device developers to build on our insights, potentially reducing the performance gap in efficiency and adaptability between able-bodied human walking and artificial walking.},
degree_type = {PhD},
school = {University of Stuttgart},
address = {Stuttgart, Germany},
month = mar,
year = {2026},
note = {Faculty of Civil and Environmental Engineering},
author = {Kiss, Bernadett},
month_numeric = {3}
}