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Motion Planning of Extreme Locomotion Maneuvers Using Multi-Contact Dynamics and Numerical Integration. Luis Sentis and Mike Slovich. The Human Center Robotics Laboratory (HCRL) The University of Texas at Austin. Humanoids 2011,Bled, Slovenia October 28 th , 2011.
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Motion Planning of Extreme Locomotion Maneuvers Using Multi-Contact Dynamics and Numerical Integration Luis Sentis and Mike Slovich The Human Center Robotics Laboratory (HCRL) The University of Texas at Austin Humanoids 2011,Bled, Slovenia October 28th, 2011
What Are Extreme Maneuvers (EM)?(Generalization of recreational free-running) Tackles discrete surfaces and near-vertical terrains Needed for humanoids, assistive devices and biomechanical studies
Objectives of the research Develop new dynamical models and numerical techniques to predict, plan and analyze EM Develop whole-body adaptive torque controllers to execute the motion plans and the desired multi-contact behaviors Build a nimble bipedal robot to verify the methods
State of the art Rough terrain still dominated by methods that do not taking into account friction characteristics No generalization of gait to discrete terrains with near-vertical surfaces Multicontact dynamics are largely overlooked Linearization is too commonly used instead of tackling the full nonlinear problems
Our approach to EM Model multicontact and single-contact dynamics Develop geometric path dependencies Use path dependencies to reduce dimensionality of the dynamic problems Derive set of rules for feasiblegeometric paths Given step conditions, use numerical integration to predict the nonlinear behavior in forward and backward times Choose as the contact planning strategy the intersections in state space of maneuvering curves Conduct comparative analysis with a human
Let’s start with multicontact dynamics fr Hands and feet are in contact acom acom fr(LF) fr(RF) ft mn ft In IROS’09, TRO’10 we presented the Virtual Linkage Model and the Multi-Contact / Grasp Matrix for humanoids Only feet are in contact
Model for single-contact dynamics(established area of research) Non-linear pendulum dynamics (balance of inertial-gravitational-reaction moments) actuated linear motor cop = center of pressure (contact point) - The form of the model is: passive hinge Solving multivariate NL systems is difficult
Resort to modeling arbitrary geometric paths Geometric dependencies are model as:
Dimensional Reduction of Models Using the previous dependencies the actuated non-linear pendulum becomes The model becomes now an ODE:
Given the piecewise linear model analyze feasible geometric paths FALL!! is angle of attack
Example: design of geometric path GOOD! UNFEASIBLE
If we consider non-linear geometric paths, dynamics are non-linear
Then, prediction by Numerical Integration Establishing geometric dependencies: Consider discrete solutions (Taylor expansion): Time perturbation is: State space solution: Reduction of single contact dynamics (Non linear behavior):
Solving the multicontact behavior FRICTION CONE
Planning of contact transitions BWD Apex Search-based to reach apex with zero velocity FWD FWD Apex
Results and Comparison with Human PLANNER HUMAN HUMAN PLANNER
Design setpoint CoM Path Rough Terrain 0.4 m
How is that possible? In the absence of forces -> parabola
Angle of attack positive Details on forces
Let’s start with multicontact dynamics fr Hands and feet are in contact acom acom fr(LF) fr(RF) ft mn ft In IROS’09, TRO’10 we presented the Virtual Linkage Model and the Multi-Contact / Grasp Matrix for humanoids Only feet are in contact