Figueiredo, MónicaAlves, Luis NeroRibeiro, Carlos2025-05-262025-05-262017-10M. Figueiredo, L. N. Alves and C. Ribeiro, "Lighting the Wireless World: The Promise and Challenges of Visible Light Communication," in IEEE Consumer Electronics Magazine, vol. 6, no. 4, pp. 28-37, Oct. 2017, doi: 10.1109/MCE.2017.27147212162-22482162-2256http://hdl.handle.net/10400.8/12990Light-emitting diodes (LEDs) are becoming increasingly ubiquitous. They can be found in illumination appliances, phones, TVs, advertising panels, dashboards, and traffic signals, among others. Most illumination applications are becoming LED based, mainly due to their long operational lifetime and high energy efficiency, which is nowadays higher than 100 lm/W [1]. Other benefits include enhanced sustainability, a compact form factor, easier maintenance, and lower cost. For these reasons, LED lighting is expected to have a market share of 84% in the general illumination market by 2030 [2]. However, there is another characteristic that is not being fully exploited: LEDs are capable of switching their light intensity at a rate that is imperceptible to the human eye. This property has been used for dimming purposes but can also be utilized in the opportunistic deployment of value-added services based on visible light communication (VLC). Since 2011, VLC technology has gained momentum, supported by the release of the IEEE 802.15.7 draft standard [3] that defines the physical and medium-access control layers. This norm specifies data rates of up to 96 megabits/s for indoor and outdoor applications [3]. Since then, several research demonstrators have shown that VLC is capable of achieving gigabits-per-second transmission with commercial off-the-shelf red-green-blue (RGB) and phosphorescent white LEDs [4]. This is the result of the increasing attention that this technology has attracted in both the research community and global society in recent years. Figure 1 illustrates this trend over the last five years by depicting the number of results for the search term visible light communication conducted using the IEEE Xplore online library and Google search engine. A key VLC requirement is that it must be based on illumination-grade LEDs and comply with the illumination requirements and safety recommendations [5]. Also, data transmission should have minimal impact on LED performance, such as color temperature, color rendering index, and lifetime [6]. Most state-of-the-art VLC demonstrators have already proved they can achieve data rates compatible with the envisioned applications, but they do not address lighting quality issues. Thus, further investigation is still necessary to guarantee the seamless integration of lighting and communication services, which is crucial for the general deployment of this technology [7]. A pertinent question that one might ask is, “Why use light signals when we can use radio-frequency (RF) signals to communicate?” The visible light spectrum can be used synergistically with common radio technology. First, as the available RF bandwidth is limited, highly regulated, and increasingly congested, it may be helpful to use a portion of the spectrum that is unlicensed, currently largely unused, and amenable to spatial reuse. This is especially relevant in the realm of technologies beyond fifth generation (5G), where the density of users and devices with communication needs is predicted to scale up exponentially. Second, there are many application scenarios where the use of radio signals raises concerns related to e-smog, privacy, and security. Third, in scenarios where line of sight (LOS) and locality are important and the illumination infrastructure is already deployed (e.g., offices, stores, or vehicles), VLC can be a complement to current RF communications. Finally, light can be a good medium for low-cost and/or low-latency short-range links for near-field communications or high-bandwidth download links. Table 1 shows the most relevant visible light and RF signal characteristics, highlighting their complementarity. Broadcasting content to end users is the most natural service envisioned for directional technologies such as VLC. Luminaires are supposed to transmit a low- [8] or high-data-rate service [9] for end users located in their illumination area. However, VLC can also be used for full duplex communication, as long as the uplink and downlink can be separated [10]. This can be done by division in wavelength, in time, or in code or by resorting to spatial isolation. Alternatively, VLC can be combined with RF in heterogeneous networks [11]; VLC provides a high-capacity, uncongested, and unregulated downlink path, while RF is used in the uplink, where congestion is less likely. In the past couple of years, several interesting surveys have been published on VLC. Some are focused on physical-layer techniques [12], while others cover medium-access protocols [13], networking techniques and sensing [14], and lighting requirements [15]. A survey on more general optical wireless communications can be found in [16]. In this article, we provide a brief state-of-the-art overview of the technology and the main upcoming challenges.engLightingRadio frequencyLight emitting diodesWireless communicationConsumer electronicsInternetjournal article10.1109/mce.2017.2714721