A new technique lets everyday objects like posters and T-shirts communicate directly with your car radio or smartphone.
For example, bus stop billboards could send digital content about local attractions. A street sign could broadcast the name of an intersection or notice that it is safe to cross a street, improving accessibility for people with disabilities. In addition, clothing with integrated sensors could monitor vital signs and send them to a phone.
“So what we do is basically make each of these everyday objects into a mini FM radio station at almost zero power.”
“What we want to do is enable smart cities and fabrics where everyday objects in outdoor environments—whether it’s posters or street signs or even the shirt you’re wearing—can ‘talk’ to you by sending information to your phone or car,” says Shyam Gollakota, assistant professor of computer science and engineering at the University of Washington.
“The challenge is that radio technologies like WiFi, Bluetooth, and conventional FM radios would last less than half a day with a coin cell battery when transmitting,” says coauthor and electrical engineering doctoral student Vikram Iyer. “So we developed a new way of communication where we send information by reflecting ambient FM radio signals that are already in the air, which consumes close to zero power.”
The team has—for the first time—demonstrated how to apply a technique called “backscattering” to outdoor FM radio signals. The new system transmits messages by reflecting and encoding audio and data in these signals that are ubiquitous in urban environments, without affecting the original radio transmissions. Results appear in a paper to be presented in Boston at the 14th USENIX Symposium on Networked Systems Design and Implementation in March.
The team demonstrated that a “singing poster” for the band Simply Three placed at a bus stop could transmit a snippet of the band’s music, as well as an advertisement for the band, to a smartphone at a distance of 12 feet or to a car over 60 feet away. They overlaid the audio and data on top of ambient news signals from a local NPR radio station.
“FM radio signals are everywhere. You can listen to music or news in your car and it’s a common way for us to get our information,” says coauthor and computer science and engineering doctoral student Anran Wang. “So what we do is basically make each of these everyday objects into a mini FM radio station at almost zero power.”
Such ubiquitous low-power connectivity can also enable smart fabric applications such as clothing integrated with sensors to monitor a runner’s gait and vital signs that transmits the information directly to a user’s phone. In a second demonstration, the researchers from the UW Networks & Mobile Systems Lab used conductive thread to sew an antenna into a cotton T-shirt, which was able to use ambient radio signals to transmit data to a smartphone at rates up to 3.2 kilobits per second.
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The system works by taking an everyday FM radio signal broadcast from an urban radio tower. The “smart” poster or T-shirt uses a low-power reflector to manipulate the signal in a way that encodes the desired audio or data on top of the FM broadcast to send a “message” to the smartphone receiver on an unoccupied frequency in the FM radio band.
“Our system doesn’t disturb existing FM radio frequencies,” says coauthor Joshua Smith, associate professor of computer science and engineering and of electrical engineering. “We send our messages on an adjacent band that no one is using—so we can piggyback on your favorite news or music channel without disturbing the original transmission.”
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The team demonstrated three different methods for sending audio signals and data using FM backscatter: one simply overlays the new information on top of the existing signals, another takes advantage of unused portions of a stereo FM broadcast, and the third uses cooperation between two smartphones to decode the message.
“Because of the unique structure of FM radio signals, multiplying the original signal with the backscattered signal actually produces an additive frequency change,” says coauthor Vamsi Talla, a postdoctoral researcher in computer science and engineering. “These frequency changes can be decoded as audio on the normal FM receivers built into cars and smartphones.”
In the team’s demonstrations, the total power consumption of the backscatter system was 11 microwatts, which could be easily supplied by a tiny coin-cell battery for a couple of years, or powered using tiny solar cells.
The National Science Foundation and Google Faculty Research Awards contributed funding to the project.
Source: University of Washington