Experience-Based Adaptation of Locomotion Behaviors for Kinematically Complex Robots in Unstructured Terrain
series DFKI Documents, volume 15-03, Sep/2015. DFKI GmbH, Universität Bremen.
Kinematically complex robots such as legged robots provide a large degree of mobility and flexibility, but
demand a sophisticated motion control, which has more tunable parameters than a general planning and
decision layer should take into consideration. A lot of parameterizations exist which produce locomotion
behaviors that fulfill the desired action but with varying performance, e.g., stability or efficiency. In addition,
the performance of a locomotion behavior at any given time is highly depending on the current environmental
context. Consequently, a complex mapping is required that closes the gap between robot-independent actions
and robot-specific control parameters considering the environmental context and a given prioritization of
In the proposed approach, the robot learns from experiences made during its interaction with the environment.
A knowledge base is created which links locomotion behaviors with performance features for visited contexts.
This behavior library is utilized by a case-based reasoner to select motion control parameters for a desired
action within the current context. The paper provides an overview of the control approach, the algorithms
used to determine the current context and the robot’s performance, as well as a description of the reasoner
which selects appropriate locomotion behaviors.
In experiments, different behavior libraries were automatically built when operators had to control a walking
robot manually through obstacle courses. Afterwards, the collected experiences and a trajectory follower
were used to traverse an obstacle course autonomously. The provided experimental evaluation shows the
performance dependency of the autonomous control with respect to different sizes and qualities of utilized
behavior libraries and compares it to manual control.
Please note that the corresponding paper is published in:
Experience-based adaptation of locomotion behaviors for kinematically complex robots in unstructured terrain;
A. Dettmann, A. Born, S. Bartsch, and F. Kirchner; In IEEE/RSJ International Conference on Intelligent
Robots and Systems (IROS), 2015.