1 research outputs found
Optimization of Robot Tasks with Cartesian Degrees of Freedom using Virtual Joints
A common task in robotics is unloading identical goods from a tray with
rectangular grid structure. This naturally leads to the idea of programming the
process at one grid position only and translating the motion to the other grid
points, saving teaching time. However this approach usually fails because of
joint limits or singularities of the robot. If the task description has some
redundancies, e.g. the objects are cylinders where one orientation angle is
free for the gripping process, the motion may be modified to avoid workspace
problems. We present a mathematical algorithm that allows the automatic
generation of robot programs for pick-and-place applications with structured
positions when the workpieces have some symmetry, resulting in a Cartesian
degree of freedom for the process. The optimization uses the idea of a virtual
joint which measures the distance of the desired TCP to the workspace such that
the nonlinear optimization method is not bothered with unreachable positions.
Combined with smoothed versions of the functions in the nonlinear program
higher order algorithms can be used, with theoretical justification superior to
many ad-hoc approaches used so far.Comment: 3. OTH-Clusterkonferenz, April 13th 2018, OTH Amberg-Weide