Efficient recursive dynamics algorithms for operational-space control with application to legged locomotion

This paper presents new recursive dynamics algorithms that enable operational-space control of floating-base systems to be performed at faster rates. This type of control approach requires the computation of operational-space quantities and suffers from high computational order when these quantities...

Full description

Saved in:
Bibliographic Details
Published in:Autonomous robots 2015-04, Vol.38 (4), p.363-381
Main Authors: Wensing, Patrick M., Palmer, Luther R., Orin, David E.
Format: Article
Language:English
Subjects:
Algorithms
Artificial Intelligence
Computation
Computational efficiency
Computer Imaging
Computer simulation
Contact
Contact force
Control
Dynamical systems
Dynamics
Engineering
Floating structures
Grounds
Jacobians
Locomotion
Mass matrix
Mechatronics
Pattern Recognition and Graphics
Pitch (inclination)
Recursive
Robotics
Robotics and Automation
Roll stabilizers
Rolling motion
System effectiveness
Vision
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:This paper presents new recursive dynamics algorithms that enable operational-space control of floating-base systems to be performed at faster rates. This type of control approach requires the computation of operational-space quantities and suffers from high computational order when these quantities are directly computed through the use of the mass matrix and Jacobian from the joint-space formulation. While many efforts have focused on efficient computation of the operational-space inertia matrix Λ , this paper provides a recursive algorithm to compute all quantities required for floating-base control of a tree-structure mechanism. This includes the first recursive algorithm to compute the dynamically consistent pseudoinverse of the Jacobian J ¯ for a tree-structure system. This algorithm is extended to handle arbitrary contact constraints with the ground, which are often found in legged systems, and uses effective ground contact dynamics approximations to retain computational efficiency. The usefulness of the algorithm is demonstrated through application to control of a high-speed quadruped trot in simulation. Our contact-consistent algorithm demonstrates pitch and roll stabilization for a large dog-sized quadruped running at 3.6 m/s without any contact force sensing, and is shown to outperform a simpler Raibert-style posture controller. In addition, the operational-space control approach allows the dynamic effects of the swing legs to be effectively accounted for at this high speed.
ISSN:0929-5593
1573-7527
DOI:10.1007/s10514-015-9420-9