Differential Dynamic Programming for Multi-Phase Rigid Contact Dynamics
April 10, 2019 Β· Declared Dead Β· π IEEE-RAS International Conference on Humanoid Robots
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Authors
Rohan Budhiraja, Justin Carpentier, Carlos Mastalli, Nicolas Mansard
arXiv ID
1904.05072
Category
cs.RO: Robotics
Cross-listed
cs.AI,
eess.SY
Citations
91
Venue
IEEE-RAS International Conference on Humanoid Robots
Last Checked
4 months ago
Abstract
A common strategy today to generate efficient locomotion movements is to split the problem into two consecutive steps: the first one generates the contact sequence together with the centroidal trajectory, while the second one computes the whole-body trajectory that follows the centroidal pattern. Yet the second step is generally handled by a simple program such as an inverse kinematics solver. In contrast, we propose to compute the whole-body trajectory by using a local optimal control solver, namely Differential Dynamic Programming (DDP). Our method produces more efficient motions, with lower forces and smaller impacts, by exploiting the Angular Momentum (AM). With this aim, we propose an original DDP formulation exploiting the Karush-Kuhn-Tucker constraint of the rigid contact model. We experimentally show the importance of this approach by executing large steps walking on the real HRP-2 robot, and by solving the problem of attitude control under the absence of external forces.
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