Dynamically Consistent Online Adaptation of Fast Motions for Robotic Manipulators

Alexander Pekarovskiy, Thomas Nierhoff, Sandra Hirche, Martin Buss

Research output: Contribution to journalArticlepeer-review

23 Scopus citations

Abstract

The planning and execution of real-world robotic tasks largely depends on the ability to generate feasible motions online in response to changing environment conditions or goals. A spline deformation method is able to modify a given trajectory so that it matches the new boundary conditions, e.g., on positions, velocities, accelerations, etc. At the same time, the deformed motion preserves velocity, acceleration, jerk, or higher derivatives of motion profile of the precalculated trajectory. The deformed motion possessing such properties can be expressed by translation of original trajectory and spline interpolation. This spline decomposition considerably reduces the computational complexity and allows real-time execution. Formal feasibility guarantees are provided for the deformed trajectory and for the resulting torques. These guarantees are based on the special properties of Bernstein polynomials used for the deformation and on the structure of the chosen computed-torque control scheme. The approach is experimentally evaluated in a number of planar volleyball experiments using 3 degree-of-freedom robots and human participants.

Original languageEnglish
Article number8107561
Pages (from-to)166-182
Number of pages17
JournalIEEE Transactions on Robotics
Volume34
Issue number1
DOIs
StatePublished - Feb 2018

Keywords

  • Manipulation planning
  • motion adaptation
  • motion control
  • path planning for manipulators

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