Abstract
As a promising approach to implement indoor positioning, visible light positioning (VLP) based on optical camera communication (OCC) image sensor has attracted substantial attention. However, the decoding schemes of existing VLP systems still face many challenges. First, the transmission channel between transmitters and receivers can be easily affected by environmental changes, resulting in poor thresholding performance. Second, the inherently unsynchronized air transmission channel issue remains a big obstacle for decoding data. The above two problems limit the application of VLP systems, where various mobile devices are used as receivers and the properties of transmission channel are constantly changing with the movement of receivers. In this paper, a universal and effective decoding scheme named pixel-to-bit calculation (PBC) decoding algorithm for VLP systems is proposed and experimentally demonstrated. It includes a Staged Threshold Scheme which provides excellent thresholding performance for different transmission channel conditions, as well as a Synchronous Decoding Operation to automatically synchronize the clock between transmitters and receivers. A decoding rate of 95.62% at the height of 2.73 m is realized in a practical Robotic-based VLP system embedded with our proposed PBC decoding scheme. In addition, experimental results show that the average decoding rate of the proposed PBC decoding scheme reaches 99.9% when applying different transmitters and receivers.
Highlights
With the ever-growing demand for various indoor location-based services (LBS) [1], indoor positioning systems have attracted intensive investigations in recent years
We implement a practical Robotic-based visible light positioning (VLP) system embedded with our proposed pixel-to-bit calculation (PBC) decoding scheme
This paper only focuses on decoding process, the proposed PBC decoding scheme is evaluated in a practical real-time Roboticbased VLP system rather than testing the decoding process separately [29]
Summary
With the ever-growing demand for various indoor location-based services (LBS) [1], indoor positioning systems have attracted intensive investigations in recent years. Global Positioning System (GPS) cannot provide accurate indoor location information since the signals would be blocked by buildings. Due to the booming development of green lighting technology, visible light positioning (VLP) has attracted researcher’s attention for its great potential in the field of indoor positioning [2,3,4]. VLP systems can utilize the visible light beams as the medium to transmit related LED location information for further position calculation. The hardware cost is reduced greatly since VLP utilizes the common LED lights in modern buildings to provide accurate positioning without resorting to any other specialized infrastructure. The image sensor (IS)-based VLP has a great advantage in realizing indoor positioning
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