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Experience- and Model-based Transformational Learning of Symbolic Behavior Specifications (bibtex)
by M Beetz and T Belker
Abstract:
The paper describes Xfrml, a system that learns symbolic behavior specifications to control and improve the continuous sensor-driven navigation behavior of an autonomous mobile robot. The robot is to navigate between a set of predefined locations in an office environment and employs a navigation system consisting of a path planner and a reactive collision avoidance system. XfrmLearn rationally reconstructs the continuous sensor-driven navigation behavior in terms of task hierarchies by identifying significant structures and commonalities in behaviors. It also constructs a statistical behavior model for typical navigation tasks. The behavior model together with a model of how the collision avoidance module should "perceive" the environment is used to detect behavior "flaws", diagnose them, and revise the plans to improve their performance. The learning method is implemented on an autonomous mobile robot.
Reference:
Experience- and Model-based Transformational Learning of Symbolic Behavior Specifications (M Beetz and T Belker), In Proceedings of the IJCAI Workshop on Robot Action Planning, 1999. (IJCAI Workshop on Robot Action Planning)
Bibtex Entry:
@inproceedings{beetz_experience-_1999,
author = {M Beetz and T Belker},
title = {Experience- and Model-based Transformational Learning of Symbolic
Behavior Specifications},
booktitle = {Proceedings of the {IJCAI} Workshop on Robot Action Planning},
year = {1999},
abstract = {The paper describes Xfrml, a system that learns symbolic behavior
specifications to control and improve the continuous sensor-driven
navigation behavior of an autonomous mobile robot. The robot is to
navigate between a set of predefined locations in an office environment
and employs a navigation system consisting of a path planner and
a reactive collision avoidance system. {XfrmLearn} rationally reconstructs
the continuous sensor-driven navigation behavior in terms of task
hierarchies by identifying significant structures and commonalities
in behaviors. It also constructs a statistical behavior model for
typical navigation tasks. The behavior model together with a model
of how the collision avoidance module should "perceive" the environment
is used to detect behavior "flaws", diagnose them, and revise the
plans to improve their performance. The learning method is implemented
on an autonomous mobile robot.},
}
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