Title :
KVP: A knowledge of volumes approach to robot task planning
Author :
Gaschler, Andre ; Petrick, Ronald P. A. ; Giuliani, Manuel ; Rickert, Markus ; Knoll, Aaron
Author_Institution :
Fortiss GmbH, Tech. Univ. Munchen, Munich, Germany
Abstract :
Robot task planning is an inherently challenging problem, as it covers both continuous-space geometric reasoning about robot motion and perception, as well as purely symbolic knowledge about actions and objects. This paper presents a novel “knowledge of volumes” framework for solving generic robot tasks in partially known environments. In particular, this approach (abbreviated, KVP) combines the power of symbolic, knowledge-level AI planning with the efficient computation of volumes, which serve as an intermediate representation for both robot action and perception. While we demonstrate the effectiveness of our framework in a bimanual robot bartender scenario, our approach is also more generally applicable to tasks in automation and mobile manipulation, involving arbitrary numbers of manipulators.
Keywords :
geometry; inference mechanisms; manipulators; robot programming; task analysis; KVP; continuous-space geometric reasoning; intermediate representation; knowledge of volumes approach; manipulators; mobile manipulation; robot motion; robot perception; robot task planning; symbolic knowledge; Cognition; Collision avoidance; Databases; Planning; Robot sensing systems;
Conference_Titel :
Intelligent Robots and Systems (IROS), 2013 IEEE/RSJ International Conference on
Conference_Location :
Tokyo
DOI :
10.1109/IROS.2013.6696354
