What’s the point of having a self-driving car if you still have to get out to plug it in? That’s a good question, says Alphabet, Google’s parent company. With that in mind, it is testing wireless charging systems for its electric self-driving cars. Documents filed at the U.S. Federal Communications Commission (FCC) suggest that Google is working toward cutting its robocars’ charger cables and beaming power to them instead.
The filings reveal that Google has been testing two wireless charging systems for its prototype electric self-driving cars in California. In February 2015, Hevo Power, a New York–based start-up, received permission from the FCC to install an experimental charger at Google’s headquarters in Mountain View, Calif. Momentum Dynamics, located in the suburbs of Philadelphia, followed in July. The address on Momentum’s filing corresponds to the secretive X division where Google’s self-driving cars are being developed.
Both companies’ systems transfer power from a transmitter embedded in the ground to a receiver on the underside of an electric vehicle, using a principle called resonant magnetic induction. In this process, an alternating current passing through a tuned electrical circuit creates an oscillating magnetic field. That field then induces another alternating current in a second, nearby circuit tuned to the same resonant frequency.
Hevo’s installation at the Googleplex involved a prototype charger, called Alpha, that can deliver 1.5 kilowatts of power from a circular transmitter “embedded like a manhole cover” in pavement. Momentum Dynamics claims that it has developed wireless transmitters with power ratings of up to 200 kW—although the FCC filings did not disclose the specifications of the system Google is using.
Google engineers are now testing multiple chargers from Momentum Dynamics at Google’s HQ in Mountain View, and at the Castle Commerce Center, the former U.S. Air Force base in Atwater, Calif., where Google’s prototype vehicles undergo completely driverless testing.
Wireless charging will be essential if Google’s vehicles are to realize the vision of Chris Urmson, director of its self-driving car program. “We’ve heard countless stories from people who need a fully self-driving car today,” he wrote in December. “We’ve heard from people with health conditions ranging from vision problems to multiple sclerosis to autism to epilepsy who are frustrated with their dependence on others for even simple errands.”
Few of those people—let alone children or fare-paying passengers of autonomous taxi services—can be expected to recharge their robotic rides, says Omer Onar, a researcher at Oak Ridge National Laboratory and member of the committee writing the standard for wireless vehicle charging. “One expectation from a self-driving vehicle is to receive your power wirelessly without handling a cord or a wire or a plug,” Onar told IEEE Spectrum.
Andy Daga, CEO of Momentum Dynamics, agrees: “Self-driving vehicles will require an automatic connection to the grid without any manual intervention.”
The idea is that, initially, a self-driving car would position itself briefly over a charging pad between rides, and ultimately, the infrastructure would be put in place that would allow a car to continually recharge its batteries as it travels along the road. This could allow carmakers to use smaller, lighter batteries than those required for today’s electric vehicles, which carry all their energy on board. In addition to dramatically reducing an EV’s weight and offering design freedom, it would slash the price of the electric car’s most expensive component. Daga says that Momentum’s high-power chargers can already recharge electric bus batteries in a matter of minutes, allowing them to be in service virtually 24 hours a day.
Still, wireless charging for electric passenger cars remains in its infancy. A company called Plugless Power offers one-off home charging units for owners of Nissan Leafs, Chevrolet Volts, or Cadillac ELRs, but public infrastructure is almost unheard of. This might start to change late next year, when Onar expects his committee at the Society of Automobile Engineers to issue its final standard.
The uncertainty has not stopped companies like Hevo and Momentum Dynamics from exploring partnerships with operators of fleets of electric vehicles now. One of Hevo’s prototypes is charging electric buses in Los Angeles, while Momentum Dynamics has placed systems with Lockheed Martin, FedEx, BYD in China, and Proterra electric buses in California.
There is nothing to prevent either wireless charging system from being used on a self-driving car, according to Onar. “The additional power requirement for self-driving vehicles, even with a heavy computational load, is manageable,” he says. “And while interference may be a problem, shielding should mean that the passengers and the other electronics on the vehicle shouldn’t be affected.”
Momentum Dynamics and Hevo Power declined to confirm any involvement with Google, and Google itself noted only that it tests many different technologies for its self-driving vehicles. All the prototype cars currently being tested in public are recharged using traditional conductive charging cables.
Mark Harris is an investigative science and technology reporter based in Seattle, with a particular interest in robotics, transportation, green technologies, and medical devices. He’s on Twitter at @meharris and email at mark(at)meharris(dot)com. Email or DM for Signal number for sensitive/encrypted messaging.