Scott A. Bortoff
Mitsubishi Electric Research Laboratories, Cambridge, MA, USA
Ladda ner artikelhttps://doi.org/10.3384/ecp2016954Ingår i: Proceedings of the American Modelica Conference 2020, Boulder, Colorado, USA, March 23-25, 2020
Linköping Electronic Conference Proceedings 169:6, s. 54-63
Publicerad: 2020-11-03
ISBN: 978-91-7929-900-2
ISSN: 1650-3686 (tryckt), 1650-3740 (online)
We propose an implicit, event-driven, penalty-based
method for modeling rigid body contact and collision that
is useful for design and analysis of control algorithms for
precision robotic assembly tasks. The method is based
on Baumgarte’s method of differential algebraic equation
index reduction in which we modify the conventional constraint
stabilization to model object collision, define a finite
state machine to model transition between contact and
non-contact states, and represent the robot and task object
dynamics as a single set of differential algebraic inequalities.
The method, which is realized natively in Modelica,
has some advantages over conventional penalty-based
methods: The resulting system is not numerically stiff after
the collision transient, it enforces constraints for object
penetration, and it allows for dynamic analysis of the
Modelica model beyond time-domain simulation. We provide
three examples: A bouncing ball, a ball maze, and a
delta robot controlled to achieve soft collision and maintain
soft contact with an object in its environment.
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