Scientists, including those from NASA, have developed a 'Wi-Fi microchip' for wearable devices that transmits information faster and uses less power than traditional receivers.
If the power necessary to transmit and receive information from a wearable to a computer, cellular or Wi-Fi network were reduced, users could get a lot more mileage out of the technology they are wearing before having to recharge it, researchers said.
Adrian Tang of NASA's Jet Propulsion Laboratory in Pasadena, California and M C Frank Chang at the University of California, Los Angeles, have been working on microchips for wearable devices that reflect wireless signals instead of using regular transmitters and receivers.
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"The idea is if the wearable device only needs to reflect the Wi-Fi signal from a router or cell tower, instead of generate it, the power consumption can go way down (and the battery life can go way up)," Tang said.
Information transmitted to and from a wearable device is encoded as 1s and 0s, just like data on a computer. This needs to be represented somehow in the system the wearable device uses to communicate.
When incoming energy is absorbed by the circuit, that's a "0," and if the chip reflects that energy, that's a "1." This simple switch mechanism uses very little power and allows for the fast transfer of information between a wearable device and a computer, smartphone, tablet or other technology capable of receiving the data.
The challenge for Tang and his colleagues was that the wearable device is not the only object in a room that reflects signals - so do walls, floors, ceilings, furniture and whatever other objects happen to be around.
The chip in the wearable device needs to differentiate between the real Wi-Fi signal and the reflection from the background.
To overcome background reflections, Tang and Chang developed a wireless silicon chip that constantly senses and suppresses background reflections, enabling the Wi-Fi signal to be transmitted without interference from surrounding objects.
They tested the system at distances of up to 20 feet. At about 8 feet, they achieved a data transfer rate of 330 megabits per second, which is about three times the current Wi-Fi rate, using about a thousand times less power than a regular Wi-Fi link.
A base station and Wi-Fi service are required for the system to work. To compensate for low power drain on the wearable, the computer or other technology it's communicating with must have a long battery life or be plugged in.
There are a multitude of potential applications for the new technology, including in space. For example, astronauts and robotic spacecraft could potentially use this technology to transmit images at a lower cost to their precious power supplies. This might also allow more images to be sent at a time.