Dynamic Stability of Passive Bipedal Walking on Rough Terrain: A Preliminary Simulation Study

A simplified 2D passive dynamic model was simulated to walk down on a rough slope surface defined by deterministic profiles to investigate how the walking stability changes with increasing surface roughness. Our results show that the passive walker can walk on rough surfaces subject to surface rough...

Full description

Saved in:
Bibliographic Details
Published inJournal of bionics engineering Vol. 9; no. 4; pp. 423 - 433
Main Authors Afshar, Parsa Nassiri, Ren, Lei
Format Journal Article
LanguageEnglish
Published Singapore Elsevier Ltd 01.12.2012
Springer Singapore
Subjects
Artificial Intelligence
Biochemical Engineering
Bioinformatics
Biomaterials
Biomedical Engineering and Bioengineering
Biomedical Engineering/Biotechnology
bipedal walking
Computer simulation
dynamic stability
Engineering
Floquet乘子
human locomotion
Passive dynamics
Rough terrain
Roughness
Stability
Strikes
Surface roughness
Walking
动态稳定性
双足步行
模型模拟
行走稳定性
表面粗糙度
路面
轨道稳定性
bipedal walking
rough terrain
dynamic stability
human locomotion
Online AccessGet full text
ISSN1672-6529
2543-2141
DOI10.1016/S1672-6529(11)60139-X

Cover

More Information
Summary:A simplified 2D passive dynamic model was simulated to walk down on a rough slope surface defined by deterministic profiles to investigate how the walking stability changes with increasing surface roughness. Our results show that the passive walker can walk on rough surfaces subject to surface roughness up to approximately 0.1% of its leg length. This indicates that bipedal walkers based on passive dynamics may possess some intrinsic stability to adapt to rough terrains although the maxi- mum roughness they can tolerate is small. Orbital stability method was used to quantify the walking stability before the walker started to fall over, It was found that the average maximum Floquet multiplier increases with surface roughness in a non-linear form. Although the passive walker remained orbitally stable for all the simulation cases, the results suggest that the possibility of the bipedal model moving away from its limit cycle increases with the surface roughness if subjected to additional perturbations. The number of consecutive steps before falling was used to measure the walking stability after the passive walker started to fall over. The results show that the number of steps before falling decreases exponentially with the increase in surface roughness. When the roughness magnitude approached to 0.73% of the walker's leg length, it fell down to the ground as soon as it entered into the uneven terrain. It was also found that shifting the phase angle of the surface profile has apparent affect on the system stability. This is probably because point contact was used to simulate the heel strikes and the resulted variations in system states at heel strikes may have pronounced impact on the passive gaits, which have narrow basins of attraction. These results would provide insight into how the dynamic stability of passive bipedal walkers evolves with increasing surface roughness.
Bibliography:22-1355/TB
bipedal walking, rough terrain, dynamic stability, human locomotion
A simplified 2D passive dynamic model was simulated to walk down on a rough slope surface defined by deterministic profiles to investigate how the walking stability changes with increasing surface roughness. Our results show that the passive walker can walk on rough surfaces subject to surface roughness up to approximately 0.1% of its leg length. This indicates that bipedal walkers based on passive dynamics may possess some intrinsic stability to adapt to rough terrains although the maxi- mum roughness they can tolerate is small. Orbital stability method was used to quantify the walking stability before the walker started to fall over, It was found that the average maximum Floquet multiplier increases with surface roughness in a non-linear form. Although the passive walker remained orbitally stable for all the simulation cases, the results suggest that the possibility of the bipedal model moving away from its limit cycle increases with the surface roughness if subjected to additional perturbations. The number of consecutive steps before falling was used to measure the walking stability after the passive walker started to fall over. The results show that the number of steps before falling decreases exponentially with the increase in surface roughness. When the roughness magnitude approached to 0.73% of the walker's leg length, it fell down to the ground as soon as it entered into the uneven terrain. It was also found that shifting the phase angle of the surface profile has apparent affect on the system stability. This is probably because point contact was used to simulate the heel strikes and the resulted variations in system states at heel strikes may have pronounced impact on the passive gaits, which have narrow basins of attraction. These results would provide insight into how the dynamic stability of passive bipedal walkers evolves with increasing surface roughness.
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:1672-6529
2543-2141
DOI:10.1016/S1672-6529(11)60139-X