Move over Wi-Fi, here comes Li-Fi - TechCentral

Move over Wi-Fi, here comes Li-Fi

How a Li-Fi network would work. Boston University

How a Li-Fi network would work. Boston University

The tungsten lightbulb has served us well over the century or so since it was introduced, but its days are numbered now with the arrival of LED lighting, which consumes a tenth of the power of incandescent bulbs and has a lifespan 30 times longer. Potential uses of LEDs are not limited to illumination: smart lighting products are emerging that can offer various additional features, including linking your laptop or smartphone to the Internet. Move over Wi-Fi, Li-Fi is here.

Wireless communication with visible light is, in fact, not a new idea. Everyone knows about using smoke signals on a desert island to try to capture attention. Perhaps less well known is that in the time of Napoleon much of Europe was covered with optical telegraphs, otherwise known as the semaphore.

Alexander Graham Bell, inventor of the telephone, actually regarded the photophone as his most important invention, a device that used a mirror to relay the vibrations caused by speech over a beam of light.

In the same way that interrupting (modulating) a plume of smoke can break it into parts that form an SOS message in Morse code, so visible light communications — Li-Fi — rapidly modulates the intensity of a light to encode data as binary zeroes and ones. But this doesn’t mean that Li-Fi transceivers will flicker; the modulation will be too fast for the eye to see.

The enormous and growing user demand for wireless data is placing huge pressure on existing Wi-Fi technology, which uses the radio and microwave frequency spectrum. With exponential growth of mobile devices, by 2019 more than 10bn devices are expected to exchange around 35 quintillion (1018) bytes of information each month. This won’t be possible using existing wireless technology due to frequency congestion and electromagnetic interference. The problem is most acutely felt in public spaces in urban areas, where many users try to share the limited capacity available from Wi-Fi transmitters or mobile phone network cell towers.

A fundamental communications principle is that the maximum data transfer possible scales with the electromagnetic frequency bandwidth available. The radio frequency spectrum is heavily used and regulated, and there just isn’t enough additional space to satisfy the growth in demand. So Li-Fi has the potential to replace radio and microwave frequency Wi-Fi.

Visible light spectrum has huge, unused and unregulated capacity for communications. The light from LEDs can be modulated very quickly: data rates as high as 3,5Gbit/s using a single blue LED or 1,7Gbit/s with white light have been demonstrated by researchers in our EPSRC-funded Ultra-Parallel Visible Light Communications programme.

Unlike Wi-Fi transmitters, optical communications are well-confined inside the walls of a room. This confinement might seem to be a limitation for Li-Fi, but it offers the key advantage that it is very secure: if the curtains are drawn then nobody outside the room can eavesdrop. An array of light sources in the ceiling could send different signals to different users. The transmitter power can be localised, more efficiently used and won’t interfere with adjacent Li-Fi sources. Indeed, the lack of radio frequency interference is another advantage over Wi-Fi. Visible light communications is intrinsically safe, and could end the need for travellers to switch devices to flight mode.

A further advantage of Li-Fi is that it can use existing power lines as LED lighting so no new infrastructure is needed.

The Internet of things is an ambitious vision of a hyper-connected world of objects autonomously communicating with each other. For example, your fridge might inform your smartphone that you have run out of milk, and even order it for you. Sensors in your car will directly alert you though your smartphone that your tyres are too worn or have low pressure.

 Light frequencies on the electromagnetic spectrum are underused, while to either side is congested. Philip Ronan, CC BY-SA

Light frequencies on the electromagnetic spectrum are underused, while to either side is congested. Philip Ronan, CC BY-SA

Given the number of “things” that can be fitted with sensors and controllers then network-enabled and connected, the bandwidth needed for all these devices to communicate is vast. Industry monitor Gartner predicts that 25bn such devices will be connected by 2020, but given that most of this information needs only to be transferred a short distance, Li-Fi is an attractive — and perhaps the only — solution to making this a reality.

Several companies are already offering products for visible light communications. The Li-1st from PureLiFi, based in Edinburgh, offers a simple plug-and-play solution for secure wireless point-to-point internet access with a capacity of 11,5Mbit/s — comparable to first generation Wi-Fi. Another is Oledcomm from France, which exploits the safe, non-radio frequency nature of Li-Fi with installations in hospitals.

There are still many technological challenges to tackle but already the first steps have been taken to make Li-Fi a reality. In the future your light switch will turn on much more than just illumination.The Conversation

  • Pavlos Manousiadis is research fellow, Graham Turnbull is professor and head of the School of Physics and Astronomy, and Ifor Samuel is professor of polymer optoelectronics, all at the University of St Andrews
  • This article was originally published on The Conversation
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  1. Interesting technology, but I see many issues. One big problem is that you’ll have to leave the lights on 24/7. What if I’m lying down in bed in the dark, does that mean I won’t be connected? Or will they use invisible parts of the light spectrum like infrared or ultraviolet? You will also require line of sight from your device to the light bulb, which is quite problematic. We might have to face the light bulb in order to stay connected. Alternatively, you will need multiple light bulbs in a room to cover all angles, and multiple receivers on devices.

  2. You don’t need to leave the lights on. This tech can run in an almost off state and still operate.

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