Visual Servoing with Time-delay Compensation for Humanoid Mobile Manipulator

For a visual servo system, there usually exists the problem of time-delay likely caused by long image processing and data transmission. The visual servo system of our robot is subject to two main limitations stemming from the specific commercial mobile manipulator, of which one is the large time-delay due to image transmission, whereas the other is failure to directly command each joint velocity as the visual servo's control input. In this paper, we propose a novel visual servo system to compensate the large time-delay, and we use integral of velocity which incorporating the image estimation and prediction with the kinematic model so as to achieve indirect velocity control with position based control mode joint. Our proposed visual servo system controls the neck joints of robot and keeps the object within the field of view of the camera during the approaching phase. We evaluate the proposed approach by experiment on a real wheeled humanoid robot and find the resulting performance quite promising, showing that our method is feasible and practical.