A Study on Vision-Based Backstepping Control for a Target Tracking System

This paper proposes a new method to control the pose of a camera mounted on a two-axis gimbal system for visual servoing applications. In these applications, the camera should be stable while its line-of-sight points at a target located within the camera's field of view. One of the most challenging aspects of these systems is the coupling in the gimbal kinematics as well as the imaging geometry. Such factors must be considered in the control system design process to achieve better control performances. The novelty of this study is that the couplings in both mechanism's kinematics and imaging geometry are decoupled simultaneously by a new technique, so popular control methods can be easily implemented, and good tracking performances are obtained. The proposed control configuration includes a calculation of the gimbal's desired motion taking into account the coupling influence, and a control law derived by the backstepping procedure. Simulation and experimental studies were conducted, and their results validate the efficiency of the proposed control system. Moreover, comparison studies are conducted between the proposed control scheme, the image-based pointing control, and the decoupled control. This proves the superiority of the proposed approach that requires fewer measurements and results in smoother transient responses.

Automated summary

This paper proposes a new method for controlling the pose of a camera mounted on a two-axis gimbal system for visual servoing applications, achieving better control performances by decoupling the couplings in both mechanism's kinematics and imaging geometry simultaneously. Simulation and experimental studies validate the efficiency of the proposed control system, which requires fewer measurements and results in smoother transient responses compared to other common control methods.