Abstract
As for biological mechanisms, which provide a specific functional behavior, the kinematic synthesis is not so simply applicable without deep considerations on requirements, such as the ideal trajectory, fine force control along the trajectory, and possible minimization of the energy consumption. An important approach is the comparison of acknowledged mechanisms to mimic the function of interest in a simplified manner. It helps to consider why the motion trajectory is generated as an optimum, arising from a hidden biological principle on adaptive capability for environmental changes. This study investigated with systematic methods of forward and inverse kinematics known as multibody dynamics (MBD) before going to the kinematic synthesis to explore what the ideal end-effector coordinates are. In terms of walking mechanisms, there are well-known mechanisms, yet the efficacy is still unclear. The Chebyshev linkage with four links is the famous closed-loop system to mimic a simple locomotion, from the 19th century, and recently the Theo Jansen mechanism bearing 11 linkages was highlighted since it exhibited a smooth and less-energy locomotive behavior during walking demonstrations in the sand field driven by wind power. Coincidentally, Klann (1994) emphasized his closed-loop linkage with seven links to mimic a spider locomotion. We applied MBD to three walking linkages in order to compare factors arising from individual mechanisms. The MBD-based numerical computation demonstrated that the Chebyshev, Klann, and Theo Jansen mechanisms have a common property in acceleration control during separate swing and stance phases to exhibit the walking behavior, while they have different tendencies in the total energy consumption and energy-efficacy measured by the ‘specific resistance’. As a consequence, this study for the first time revealed that specific resistances of three linkages exhibit a proportional relationship to the walking speed, which is consistent with human walking and running, yet interestingly it is not consistent with older walking machines, like ARL monopod I, II. The results imply a similarity between biological evolution and robot design, in that the Chebyshev mechanism provides the simplest walking motion with fewer linkages and the Theo Jansen mechanism realizes a fine profile of force changes along the trajectory to reduce the energy consumption acceptable for a large body size by increasing the number of links.
Highlights
Multibody dynamics (MBD) has been developed to analyze multibody systems, finite element systems, and continuous systems in a unified manner by Schiehlen [54] based on the Kane’s Method [34] and computer-aided analysis initially introduced by Nikravesh [42]
As a common property of the three closed-loop linkages, we observed a large peak point of the torque (Tb in the Chebyshev linkage and Klann mechanism, and Ta in the Theo Jansen mechanism) which was located at the swing phase before landing, and negative torque was observed at the stance phase, which contributes to separation of the swing and stance phases
The Chebyshev linkage, Klann and Theo Jansen mechanisms showed different properties in individual acceleration and torque temporal profiles, while they had consistent tendencies regarding total energy consumptions and energy-efficacies, which were proportional to the walking speed
Summary
Multibody dynamics (MBD) has been developed to analyze multibody systems, finite element systems, and continuous systems in a unified manner by Schiehlen [54] based on the Kane’s Method [34] and computer-aided analysis initially introduced by Nikravesh [42]. We introduce the MBD approach for comparing the effectiveness of movement mechanisms, including earlier proposed walking machines, using the common criterion such as the specific resistance. This systematic analysis is devoted to clarifying which property of the closed linkages has an advantage with respect to older walking machines, and the accomplishment of the qualitative comparison with the MBD reveals a similar property and dissimilarity of the three types, which is a clue to how biological walking mechanisms evolved. According to the configuration of the MBS defined by n vectors of generalized coordinates of q where t is the time, a set of kinematic constraint equations is obtained as (q, t) =. It should be noted here that the array qdoes not have to contain the actual velocity components of the system [42, 43]
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