TY - GEN
T1 - Quintic Spline Collocation for Real-Time Biped Walking-Pattern Generation with variable Torso Height
AU - Seiwald, Philipp
AU - Sygulla, Felix
AU - Staufenberg, Nora Sophie
AU - Rixen, Daniel
N1 - Publisher Copyright:
© 2019 IEEE.
PY - 2019/10
Y1 - 2019/10
N2 - This paper presents our newest findings in planning a dynamically and kinematically feasible center of mass motion for bipedal walking robots. We use a simplified robot model to incorporate multi-body dynamics and kinematic limits, while still being able to meet hard real-Time requirements. The vertical center of mass motion is obtained through interpolation of a quintic spline whose control points are projected onto the kinematically feasible region. Subsequently, the horizontal motion is computed from multi-body dynamics which we approximate by solving an overdetermined boundary value problem via spline collocation based on quintic polynomials. The proposed algorithm is an improvement of our previous method, which used a parametric torso height optimization for vertical and cubic spline collocation for horizontal components. The novel center of mass motion improves stability, especially for stepping up and down platforms. Moreover, the new method leads to a less complex overall algorithm since it removes the necessity of manually tuned parameters and strongly simplifies the incorporation of boundary values. Lastly, the new approach is more efficient, which leads to a significantly reduced total runtime. The proposed method is validated through successfully conducted simulations and experiments on our humanoid robot platform, LoLA.
AB - This paper presents our newest findings in planning a dynamically and kinematically feasible center of mass motion for bipedal walking robots. We use a simplified robot model to incorporate multi-body dynamics and kinematic limits, while still being able to meet hard real-Time requirements. The vertical center of mass motion is obtained through interpolation of a quintic spline whose control points are projected onto the kinematically feasible region. Subsequently, the horizontal motion is computed from multi-body dynamics which we approximate by solving an overdetermined boundary value problem via spline collocation based on quintic polynomials. The proposed algorithm is an improvement of our previous method, which used a parametric torso height optimization for vertical and cubic spline collocation for horizontal components. The novel center of mass motion improves stability, especially for stepping up and down platforms. Moreover, the new method leads to a less complex overall algorithm since it removes the necessity of manually tuned parameters and strongly simplifies the incorporation of boundary values. Lastly, the new approach is more efficient, which leads to a significantly reduced total runtime. The proposed method is validated through successfully conducted simulations and experiments on our humanoid robot platform, LoLA.
UR - http://www.scopus.com/inward/record.url?scp=85082660120&partnerID=8YFLogxK
U2 - 10.1109/Humanoids43949.2019.9035076
DO - 10.1109/Humanoids43949.2019.9035076
M3 - Conference contribution
AN - SCOPUS:85082660120
T3 - IEEE-RAS International Conference on Humanoid Robots
SP - 56
EP - 63
BT - 2019 IEEE-RAS 19th International Conference on Humanoid Robots, Humanoids 2019
PB - IEEE Computer Society
T2 - 19th IEEE-RAS International Conference on Humanoid Robots, Humanoids 2019
Y2 - 15 October 2019 through 17 October 2019
ER -