Discrete-time robot visual feedback systems with nonlinear depth adaptation: stability analysis and experiments

Author

Conticelli, Fabio ; Allotta, Benedetto

Author_Institution

Scuola Superiore Sant´´Anna, Pisa, Italy

Volume

4

fYear

2000

fDate

2000

Firstpage

3951

Abstract

In this paper, a nonlinear adaptive visual feedback scheme is designed to perform 3D positioning tasks, consisting in the regulation of the relative pose between a robotic camera and a rigid object of interest. The dynamical system of robotic camera-object interaction is expressed in terms of image features, i.e. 2D points tracking in the image plane. Since the visual sampling period is not negligible at the current state of technology, a discrete-time representation of the camera-object interaction model is first derived. By exploiting nonlinear controllability properties, a Lyapunov-based discrete-time control law is designed to ensure asymptotic stability in the image reference set-point. Moreover, a 3D adaptation procedure, in a case of unknown object depth, ensures ultimate boundedness of the whole state vector

Keywords

adaptive control; asymptotic stability; controllability; discrete time systems; feedback; nonlinear control systems; optical tracking; robot dynamics; robot vision; 2D points tracking; Lyapunov method; adaptive control; asymptotic stability; camera-object interaction; controllability; depth adaptation; discrete-time systems; nonlinear control system; robot vision; visual feedback; visual servoing; Adaptive control; Cameras; Control systems; Controllability; Feedback; Programmable control; Robot kinematics; Robot sensing systems; Robot vision systems; Stability analysis;

fLanguage

English

Publisher

ieee

Conference_Titel

Decision and Control, 2000. Proceedings of the 39th IEEE Conference on

Conference_Location

Sydney, NSW

ISSN

0191-2216

Print_ISBN

0-7803-6638-7

Type

conf

DOI

10.1109/CDC.2000.912331

Filename

912331