Kinematic optimization for bipedal robots: a framework for real-time collision avoidance

Arne Christoph Hildebrandt, Simon Schwerd, Robert Wittmann, Daniel Wahrmann, Felix Sygulla, Philipp Seiwald, Daniel Rixen, Thomas Buschmann

Research output: Contribution to journalArticlepeer-review

7 Scopus citations

Abstract

Bipedal locomotion is more than dynamically stable walking. The redundant kinematic design of humanoid robots allows for complex motions in complex scenarios. One challenge of current robotic research is the exploitation of the capacities of redundant robots in real-time applications. In this paper, we present and evaluate methods for real-time motion generation of redundant robots. The proposed methods are based on a model-predictive approach. We propose and compare methods for optimization of robot motions defined by parameterized task-space trajectories and for redundancy resolution. The approaches are successfully combined in a novel algorithm. The methods are introduced with the help of a minimal model. It shows their applicability for a wide range of complex robotic systems. We apply and validate their effectiveness and their real-time character in several experiments with different environments with the humanoid robot Lola.

Original languageEnglish
Pages (from-to)1187-1205
Number of pages19
JournalAutonomous Robots
Volume43
Issue number5
DOIs
StatePublished - 15 Jun 2019

Keywords

  • Autonomous navigation
  • Bipedal walking
  • Collision avoidance
  • Kinematic optimization
  • Real-time motion generation

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