Technology is constantly improving and evolving to offer new means of accessing the internet. The most recent one is Li-Fi or Light Fidelity, a kind of wireless communication that transmits data using light. Unlike Wi-Fi, it does not rely on radio waves and works with visible light. This makes it a very promising alternative for fast and secure access to the internet.
Li-Fi technology uses LED bulbs that transfer data by transmitting through light signals. Data is implanted into the waves of light, and a photodetector captures the same, changing these signals into digital information. Hence, it facilitates ultra-fast data transfer since the speed of light waves is far more significant than radio waves. Because Li-Fi depends on visible light, it fails to penetrate walls, making it much more secure than the rest.
Li-Fi can be used at a rate of 100 times faster than Wi-Fi. Laboratory experiments show speeds to reach more than 100 Gbps, far exceeding the standard speeds of most Wi-Fi connections. This high speed enables Li-Fi for applications involving rapid data transfer, including video streaming, online gaming, and cloud computing.
Since Li-Fi signals do not penetrate walls, unauthorized access is more complicated. This feature makes Li-Fi suitable for sensitive environments like government offices, hospitals, and financial institutions where data security is crucial.
With more devices being connected, Wi-Fi tends to be congested, giving users slower speeds and connectivity problems. Li-Fi, on the other hand, exists in the visible light spectrum much wider than the radio frequency spectrum, bringing much lower network congestion and interference.
Li-Fi can be easily integrated into the existing lighting system, thus eliminating the need for extra power sources. LED bulbs, already used for illumination, can be used as data transmitters, therefore making the system energy-efficient.
Wi-Fi signals cause radio waves that interfere with electronic devices, especially in hospitals and airplanes. Since Li-Fi uses light waves, it has no possibility of causing electromagnetic interference, thus making it safer in sensitive areas.
Li-Fi needs a direct line of sight between the transmitter and receiver, which limits its range. Unlike Wi-Fi, which can cover large areas, Li-Fi's effectiveness is restricted to the space illuminated by the light source.
Since Li-Fi relies on light, it fails to work when completely dark. The light source has to be turned on for the connection. That limits it a little more when one wants steady connectivity in some situations.
Widespread adoption of Li-Fi requires significant changes to existing infrastructure. LED bulbs must be equipped with Li-Fi transmitters, and devices need compatible receivers. Upgrading infrastructure might involve costs and effort, thus slowing its implementation.
Most modern electronic devices are Wi-Fi-enabled, while Li-Fi support is very low. Until manufacturers develop Li-Fi-compatible devices, the technology will have a limited number of adopters.
The future of Li-Fi is believed to transform wireless internet connectivity. It shall overcome its main limitations and develop hybrid systems along with Wi-Fi. Although it may not achieve priority over other aspects like security, speed, and efficiency in areas and locations where that is required, Li-Fi can take a good role.
This technology will be applied to smart cities, industrial automation, and healthcare facilities. With the growing demand for high-speed and faster internet, Li-Fi may be an essential element shortly of next-generation communication systems.
Even though Li-Fi cannot be replaced by Wi-Fi, it is a powerful addition to the currently prevailing wireless networks. Over time, it will become part of daily internet usage and contribute to molding the future of wireless communication.