Pre-print of paper presented at Intelligent Robots and Systems (IROS 2014), IEEE International Conference on, Chicago, USA, 2014Legged robots are typically in rigid contact with the environment at multiple locations, which add a degree of complexity to their control. We present a method to control the motion and a subset of the contact forces of a floating-base robot. We derive a new formulation of the lexicographic optimization problem typically arising in multitask motion/force control frameworks. The structure of the constraints of the problem (i.e. the dynamics of the robot) allows us to find a sparse analytical solution. This leads to an equivalent optimization with reduced computational complexity, comparable to inverse-dynamics based approaches. At the same time, our method preserves the flexibility of optimization based control frameworks. Simulations were carried out to achieve different multi-contact behaviors on a 23-degree-offreedom humanoid robot, validating the presented approach. A comparison with another state-of-the-art control technique with similar computational complexity shows the benefits of our controller, which can eliminate force/torque discontinuities

Mansard, N

Metta, G

Natale, L

Nori, F

Prete, AD

arXiv

International audienceLegged robots are typically in rigid contact with the environment at multiple locations, which add a degree of complexity to their control. We present a method to control the motion and a subset of the contact forces of a floating-base robot. We derive a new formulation of the lexicographic optimization problem typically arising in multi-task motion/force control frameworks. The structure of the constraints of the problem (i.e. the dynamics of the robot) allows us to find a sparse analytical solution. This leads to an equivalent optimization with reduced computational complexity, comparable to inverse-dynamics based approaches. At the same time, our method preserves the flexibility of optimization based control frameworks. Simulations were carried out to achieve different multi-contact behaviors on a 23-degree-of-freedom humanoid robot, validating the presented approach. A comparison with another state-of-the-art control technique with similar computational complexity shows the benefits of our controller, which can eliminate force/torque discontinuities

del Prete, Andrea

Mansard, Nicolas

Nori, Francesco

Metta, Giorgio

Natale, Lorenzo

HAL Université de Toulouse, et Toulouse INP

Partial force control of constrained floating-base robots

Scientific Publications of the University of Toulouse II Le Mirail

Legged robots are typically in rigid contact with the environment at multiple locations, which add a degree of complexity to their control. We present a method to control the motion and a subset of the contact forces of a floating-base robot. We derive a new formulation of the lexicographic optimization problem typically arising in multi-task motion/force control frameworks. The structure of the constraints of the problem (i.e. the dynamics of the robot) allows us to find a sparse analytical solution. This leads to an equivalent optimization with reduced computational complexity, comparable to inverse-dynamics based approaches. At the same time, our method preserves the flexibility of optimization based control frameworks. Simulations were carried out to achieve different multi-contact behaviors on a 23-degree-of-freedom humanoid robot, validating the presented approach. A comparison with another state-of-the-art control technique with similar computational complexity shows the benefits of our controller, which can eliminate force/torque discontinuities

Del Prete, A

PEARL (Univ. of Plymouth)

University of PlymouthPEARL https://pearl.plymouth.ac.ukFaculty of Science and Engineering School of Engineering, Computing and Mathematics2014-09Partial force control of constrainedfloating-base robotsDel Prete, Ahttp://hdl.handle.net/10026.1/953310.1109/iros.2014.69430102014 IEEE/RSJ International Conference on Intelligent Robots and SystemsIEEEAll content in PEARL is protected by copyright law. Author manuscripts are made available in accordance withpublisher policies. Please cite only the published version using the details provided on the item record ordocument. In the absence of an open licence (e.g. Creative Commons), permissions for further reuse of contentshould be sought from the publisher or author.Version 1.1 | 17.02.2016  UNIVERSITY OF PLYMOUTH  DEPOSIT LICENCE AGREEMENT FOR RESEARCH     PEARL supports the long-term preservation of research outputs, and open access to them. 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Partial Force Control of Constrained Floating-Base Robots

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