Dynamic visual servo control of robots: An adaptive image-based approach
Abstract
Sensory systems, such as computer vision, can be used to measure relative robot end-effector positions to derive feedback signals for control of end-effector positioning. The role of vision as the feedback transducer affects closed-loop dynamics, and a visual feedback control strategy is required. Vision-based robot control research has focused on vision processing issues, while control system design has been limited to ad-hoc strategies. We formalize an analytical approach to dynamic robot visual servo control systems by first casting position-based and image-based strategies into classical feedback control structures. The image-based structure represents a new approach to visual servo control, which uses image features (e.g., image areas, and centroids) as feedback control signals, thus eliminating a complex interpretation step (i.e., interpretation of image features to derive world-space coordinates). Image-based control presents formidable engineering problems for controller design, including coupled and nonlinear dynamics, kinematics, and feedback gains, unknown parameters, and measurement noise and delays. A model reference adaptive controller (MRAC) is designed to satisfy these requirements.
BibTeX
@conference{Weiss-1985-15233,author = {Lee Weiss and Arthur C. Sanderson and C. P. Neuman},
title = {Dynamic visual servo control of robots: An adaptive image-based approach},
booktitle = {Proceedings of (ICRA) International Conference on Robotics and Automation},
year = {1985},
month = {March},
pages = {662 - 668},
}