Shape from motion decomposition as a learning approach for autonomous agents

Author

Voyles, Richard M., Jr. ; Morrow, J. Dan ; Khosla, Pradeep K.

Author_Institution

Robotics Ph.D Program, Carnegie Mellon Univ., Pittsburgh, PA, USA

Volume

1

fYear

1995

fDate

22-25 Oct 1995

Firstpage

407

Abstract

This paper explores shape from motion decomposition as a learning tool for autonomous agents. Shape from motion is a process through which an agent learns the “shape” of some interaction with the world by imparting motion through some subspace of the world. The technique applies singular value decomposition to observations of the motion to extract the eigenvectors. The authors show how shape from motion applied to a fingertip force sensor “learns” a more precise calibration matrix with less effort than traditional least squares approaches. The authors also demonstrate primordial learning on a primitive “infant” mobile robot

Keywords

calibration; computer vision; eigenvalues and eigenfunctions; learning (artificial intelligence); matrix algebra; robots; singular value decomposition; tactile sensors; autonomous agents; calibration matrix; eigenvectors extraction; fingertip force sensor; learning approach; primitive infant mobile robot; primordial learning; shape from motion decomposition; singular value decomposition; Autonomous agents; Calibration; Computer vision; Force sensors; Matrix decomposition; Ontologies; Principal component analysis; Robustness; Shape; Singular value decomposition;

fLanguage

English

Publisher

ieee

Conference_Titel

Systems, Man and Cybernetics, 1995. Intelligent Systems for the 21st Century., IEEE International Conference on

Conference_Location

Vancouver, BC

Print_ISBN

0-7803-2559-1

Type

conf

DOI

10.1109/ICSMC.1995.537793

Filename

537793