Volkan RodopluKemal HocaogluAnil AdarRifat Orhan CikmazelAlper Saylam2025-10-062020216935362169-353610.1109/ACCESS.2020.2974704https://www.scopus.com/inward/record.uri?eid=2-s2.0-85081662699&doi=10.1109%2FACCESS.2020.2974704&partnerID=40&md5=96d5c31d58074db320bbd003a03dbd47https://gcris.yasar.edu.tr/handle/123456789/9304We characterize the line-of-sight (LOS) link availability in indoor visible light communication (VLC) networks based on the behavior of human users. The VLC link availability is impacted by humans in three distinct ways: (1) Users turn the lights on or off in each room. (2) Users may carry mobile devices. (3) Users constitute mobile obstacles that block or shadow the channel between the transmitter and the receiver. First we develop a mathematical framework for VLC link availability and a probabilistic model of the VLC network with respect to human behavior in indoor environments. Second we design a realistic multi-user indoor VLC system simulation with static and mobile VLC devices that are expected to be found in smart home environments. We present the following four sets of results: (1) We report statistics on the blockage durations of VLC links and categorize the links with respect to these statistics. (2) We demonstrate the performance of Selection Diversity versus Maximal Ratio Combining for mobile VLC devices carried by humans in a smart home setting. (3) We show that optimal LED resource allocation policies for multiple users are impacted by the VLC link blockage events caused by humans. (4) We demonstrate that the link blockage events in different rooms become dependent due to humans who transition between rooms. Based on our results we provide new directions for the design of network architectures for indoor VLC systems. © 2020 Elsevier B.V. All rights reserved.EnglishMobility, Network Simulation, Shadowing, Visible Light Communication (vlc), Wireless Networks, Automation, Behavioral Research, Carrier Mobility, Light, Network Architecture, Wireless Networks, Mathematical Frameworks, Maximal Ratio Combining (mrc), Network Simulation, Probabilistic Modeling, Resource Allocation Policy, Selection Diversity, Shadowing, Visible Light Communications (vlc), Visible Light CommunicationAutomation, Behavioral research, Carrier mobility, Light, Network architecture, Wireless networks, Mathematical frameworks, Maximal ratio combining (MRC), Network simulation, Probabilistic modeling, Resource allocation policy, Selection diversity, shadowing, Visible light communications (VLC), Visible light communicationArticle