In the 1890s, Nikola Tesla captured the imagination of the world with his invention of the Tesla coil, a device that could transmit electricity through the air, no wires required. More than 100 years later, the world has responded by adapting this breakthrough technology… mainly to recharge their electric toothbrushes.
But things are changing rapidly in the world of wireless power, with some new ideas coming to the forefront in the last few years. As more and more gadget makers get hip to the idea of a world without power bricks, this is a technology category that’s about to explode.
How will your phone, your lights, and even your electric car someday be powered without a wire? Here’s a primer on how wireless power works.
Today: Short-range inductive coupling
Take a device that has a battery inside and rest it on a special charging station or place it on a charging pad: This type of wireless power—which most of us have at least seen over the past few years—is known as inductive coupling. It involves two devices, but there are no visible electrodes or obvious contact points. The technology revolves around the use of magnetic fields to create an electric current.
Run electricity through a coil of wire, and it creates a magnetic field. In the typical inductive coupling scenario, this coil is found inside the base station or charging unit, which is plugged into the wall. Now take another coil of wire and place it in close proximity to (but not touching) the first coil.
In our example, this second coil is inside the toothbrush or smart phone. When the magnetic field of the first coil interacts with the second coil, it generates an electrical current. This is called induction. The current isn’t much, but then again, your toothbrush doesn’t need much power to recharge its internal battery after the couple of minutes you spend brushing your teeth each day. So, as if by magic, the device is always fully charged.
The use of inductive coupling in electric toothbrushes was born of necessity. Exposed electrodes don’t work—and in fact could be very dangerous—if they get wet. More recently, as this technology has been improved to provide greater levels of efficiency with smaller components, its primary utility is becoming one of convenience. No need to plug your phone in at home or in the car, inductive couplings located strategically in your house and vehicle can take care of it for you, automatically.
Tomorrow: Long-range inductive coupling
Inductive coupling is a neat idea, but its extremely short range—often on the scale of a few millimeters—makes it minimally useful in the real world. (The distance the current can travel depends on the diameter of the coils and the number of windings.) The bulk of research today has focused on maximizing the distance at which current can be induced, and minimizing the loss of power over that distance.
More recent research has found that you can extend the useful range of an inducted current by using materials with the same resonant frequencies. All objects have a natural resonant frequency at which they vibrate. Think of a tuning fork. It doesn’t matter how hard you hit it, it always vibrates at the same frequency, emitting a tone with the same pitch every time. When you match the resonant frequencies of the two coils in an inductive-coupling scenario, you get better efficiencies from the configuration.
The design of resonant inductive coupling circuits is a bit more complex than this, involving the attachment of a capacitor to each of the two inducting coils. Engineers can fine tune both the design of the coils and the plates to alter the resonant frequency. Ultimately, when the system is energized, an electromagnetic wave is generated that can travel from one resonant coil to the next, over much greater distances than have been capable before.
The most iconic experiments along these lines occurred at MIT in 2006 and 2007, when researchers powered a 60-watt light bulb from a range of two meters using resonant induction. The technology was given a name: WiTricity. One of the researchers, Marin Soljačić, would later go on to found a wireless power company by the same name. Today, the company sells a development kit of its Prodigy system for $995: “Your gateway to a future of a world without wires.”
The market is already stuffed to the gills with companies that are putting these technologies to use, and standards bodies are rapidly maturing.
The Qi specification is being developed by a massive group called the Wireless Power Consortium that includes Microsoft, Panasonic, Samsung, Sony, Toshiba, Verizon, and more. Qi (pronounced chee) is really a simple implementation of inductive coupling, designed to work mainly through devices in physical contact with one another.
With the goal of encouraging “snack charging” in vehicles, at desks, and during brief stops at coffee shops and cafes, the consortium now lists a total of 692 certified, compatible products on the market, mainly charging plates and cell-phone sleeves. Ikea recently announced that it would be introducing furniture with built-in charging plates for smartphones and tablets. A new version of the Qi standard extends its range from 7mm to 45mm through the use of resonant coupling. That may not sound like much, but it does make the technology much more flexible in the types of places it is implemented.
The other two groups creating wireless power specifications— the Alliance for Wireless Power (A4WP) and the Power Matters Alliance (PMA)— recently announced that they would merge . This brings together A4WP member companies such as Asus, Dell, Fujitsu, HP, Intel, and Witricity with PMA member companies Duracell, Proctor & Gamble, LG, and Starbucks.
The A4WP promotes a resonant-coupling technology dubbed Rezence, which has yet to see any widespread commercial deployments, but there are a handful of PMA-certified products now on the market. And Starbucks, for its part, had previously announced plans to roll out PMA-compatible wireless charging pads in its stores nationwide after successful pilot projects in Boston and San Francisco.
Ultimately, all three of these technologies are all similar, but the materials used all differ in the values of their resonant frequencies and the power they generate. This isn’t likely to be a major hindrance in the long term, though. Qualcomm senior director of wireless power solutions Mark Hunsicker says that device manufacturers can simply incorporate components that support both major technologies. “To implement a dual-mode receiver is relatively straightforward,” he says.
Headlong into tomorrow
How might wireless power technologies be commercialized in the future? The deployment of mammoth Tesla coils to power entire neighborhoods is an unlikely possibility, but there might be a future for wireless power outside of keeping our phone batteries topped up. With resonant induction technology increasing the range of wireless charging, furniture manufacturers are integrating charging pads into desks, bar tops, and nightstands.
Someday, full surfaces may be energized with charging technology – not just tables but floors and walls as well. Safety is a concern with all of this, of course, because one of the by-products of wireless power is heat. “In the future, the entire industry wants to see an experience similar to Wi-Fi,” says Hunsicker, “but there’s a huge regulatory challenge there.”
IEEE Fellow Stuart Lipoff notes that at this point “it’s really not clear what people find useful or are willing to invest in,” but he imagines a public wireless charging infrastructure that would free us from the tyranny of the two-prong plug. “Traffic lights at intersections would be an interesting wireless power spot” for both pedestrians and drivers, he says. It could even be easily monetized. “A wireless power station could simply look up your ID on your phone and charge you for the amount of electricity you transfer to it. With today’s battery tech, you could charge your battery halfway in just a few minutes while waiting for a light to change.”
Electric cars are another area where this technology is already on the rise. At CES this year, two companies, including BMW, demonstrated wireless vehicle-charging technology. Just park your car over a pad in your garage and the vehicle charges automatically.
What about putting chargers in the roadway then? While it’s just a concept, it’s an idea that could revolutionize road travel as we know it, keeping batteries topped up while we roll down the street.
This story, "Cutting the final cord: How wireless power and wireless charging works" was originally published by TechHive.