Feedback control of an underactuated planar bipedal robot with impulsive foot action

Jun Ho Choi; J. W. Grizzle

doi:10.1017/S0263574704001250

Abstract

A planar underactuated bipedal robot with an impulsive foot model is considered. The analysis extends previous work on a model with unactuated point feet of Westervelt et al. to include the actuator model of Kuo. The impulsive actuator at each leg end is active only during the double support phase, which results in the model being identical to the model with unactuated point feet for the single support phase. However, the impulsive foot actuation results in a different model for the double support map. Conditions for the existence of a hybrid zero dynamics for the robot with foot actuation are studied. A feedback design method is proposed that integrates actuation in the single and double support phases. A stability analysis is performed using a Poincaré return map. As in Kuo's model, a more efficient gait is demonstrated with an impulsive foot action.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Morris, B. and Grizzle, J.W. 2005. A Restricted Poincaré Map for Determining Exponentially Stable Periodic Orbits in Systems with Impulse Effects: Application to Bipedal Robots. p. 4199.

Guobiao Song and Zefran, M. 2006. Underactuated dynamic three-dimensional bipedal walking. p. 854.

Morris, B. and Grizzle, J.W. 2006. Hybrid Invariance in Bipedal Robots with Series Compliant Actuators. p. 4793.

Ohata, Ryusuke Nakaura, Shigeki and Sampei, Mitsuji 2006. A synthesis of bipedal runner by output zeroing. p. 2166.

Kohei Suseki Shigeki Nakaura and Mitsuji Sampei 2007. The running control of humanoid robot utilizing Q-learning and output zeroing. p. 5131.

Olenšek, Andrej and Matjačić, Zlatko 2008. Human-like control strategy of a bipedal walking model. Robotica, Vol. 26, Issue. 3, p. 295.

Srinivasan, S. Raptis, I. A. and Westervelt, E. R. 2008. Low-Dimensional Sagittal Plane Model of Normal Human Walking. Journal of Biomechanical Engineering, Vol. 130, Issue. 5,

Lin, J. Zhan, J. H. and Chang, Julian 2008. Stabilization and equilibrium control of a new pneumatic cart-seesaw system. Robotica, Vol. 26, Issue. 2, p. 219.

Morris, B. and Grizzle, J.W. 2009. Hybrid Invariant Manifolds in Systems With Impulse Effects With Application to Periodic Locomotion in Bipedal Robots. IEEE Transactions on Automatic Control, Vol. 54, Issue. 8, p. 1751.

Olenšek, Andrej and Matjačić, Zlatko 2011. Two-level control strategy of an eight link biped walking model. Simulation Modelling Practice and Theory, Vol. 19, Issue. 1, p. 133.

Tavakoli, Ali and Hurmuzlu, Yildirim 2013. Robotic locomotion of three generations of a family tree of dynamical systems. Part II: Impulsive control of gait patterns. Nonlinear Dynamics, Vol. 73, Issue. 3, p. 1991.

Tavakoli, Ali and Hurmuzlu, Yildirim 2013. Robotic locomotion of three generations of a family tree of dynamical systems. Part I: Passive gait patterns. Nonlinear Dynamics, Vol. 73, Issue. 3, p. 1969.

Zardashti, R Nikkhah, AA and Yazdanpanah, MJ 2015. Multi-objective trajectory planning over terrain using label-setting greedy-based algorithm. Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, Vol. 229, Issue. 8, p. 1435.

Zardashti, R. Yazdanpanah, M. J. and Nikkhah, A. A. 2016. Nonlinear Multiobjective Time-Dependent TF/TA Trajectory Planning Using a Network Flow–Based Algorithm. Journal of Aerospace Engineering, Vol. 29, Issue. 2,

Moon, Jae‐Sung Stipanović, Dušan M. and Spong, Mark W. 2016. Gait Generation and Stabilization for Nearly Passive Dynamic Walking Using Auto‐distributed Impulses. Asian Journal of Control, Vol. 18, Issue. 4, p. 1343.

Moon, Jae-Sung and Bae, Joonbum 2016. Gait optimization and energetics of ballistic walking for an underactuated biped with knees. Nonlinear Dynamics, Vol. 85, Issue. 3, p. 1533.

Weerakoon, W. M. L. T. Maithripala, D. H. S. and Berg, J. M. 2017. Feedback regularization based PD controller for a planar three-link biped robot. p. 1.

Gritli, Hassène and Belghith, Safya 2017. Walking dynamics of the passive compass-gait model under OGY-based control: Emergence of bifurcations and chaos. Communications in Nonlinear Science and Numerical Simulation, Vol. 47, Issue. , p. 308.

Giardina, Fabio and Iida, Fumiya 2017. 2016 International Symposium on Experimental Robotics. Vol. 1, Issue. , p. 113.

Nasiri, Rezvan Zare, Armin Mohseni, Omid Yazdanpanah, Mohammad Javad and Ahmadabadi, Majid Nili 2019. Concurrent design of controller and passive elements for robots with impulsive actuation systems. Control Engineering Practice, Vol. 86, Issue. , p. 166.

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Feedback control of an underactuated planar bipedal robot with impulsive foot action

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Feedback control of an underactuated planar bipedal robot with impulsive foot action

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