Single LED positioning scheme based on angle sensors in robotics

Indoor robotic localization is one of the most active areas in robotics research nowadays. Visible light positioning (VLP) is a promising indoor localization method, as it provides high positioning accuracy and allows for leveraging the existing lighting infrastructure. Apparently, accurate positioning performance is mostly shown by the VLP system with multiple LEDs, while such strict requirement of LED numbers is more likely to lead to VLP system failure in actual environments. In this paper, we propose a single-LED VLP system based on image sensor with the help of angle sensor estimation, which efficiently relaxes the assumption on the minimum number of simultaneously captured LEDs from several to one. Aiming at improving the robustness and accuracy of positioning in the process of continuous change of robot pose, two methods of visual-inertial message synchronization are proposed and used to obtain the well-matched positioning data packets. Various schemes of single-LED VLP system based on different sensor selections and message synchronization methods have been listed and compared in an actual environment. The effectiveness of the proposed single-LED VLP system based on odometer and image sensor as well as the robustness under LED shortage, handover situation and background non-signal light interference, are verified by real-world experiments. The experimental results show that our proposed system can provide an average accuracy of 2.47 cm and the average computational time in low-cost embedded platforms is around 0.184 s.