- PoWiFi routers use 'ambient backscatter' to turn Wi-Fi signals into power
- Researchers installed PoWiFi routers using this technology in six homes
- Routers powered a battery-free camera situated 17ft (5 metres) away
- Homeowners also said there was no noticeable impact on their networks
Having to charge your phone to send a message, or standing on a chair to get signal could soon be a thing of the past.
US
engineers recently developed technology known as 'ambient backscatter'
that taps into Wi-Fi signals and transforms it into power - and have
now created a prototype router.
During
trials, these so-called PoWiFi routers powered battery-free cameras
17ft (5 metres) away and did so without interfering with the homeowners'
web speeds.
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Having to charge your phone to send a
message, or standing on a chair to get signal could soon be a thing of
the past. US engineers recently developed technology known as 'ambient
backscatter' that taps into Wi-Fi signals and transforms it into power -
and have now tested a prototype router in six homes
The
technology was first showcased by researchers at Washington University
in August but lead engineer Shyam Gollakota recently demonstrated the
prototype router at the EmTech Digital conference.
His team installed its PoWiFi router in six homes and asked homeowners to use it for normal internet access for 24 hours.
Ambient
backscatter, also known as Wi-Fi backscatter, on which the technology
is based, enables two battery-free RF-powered devices to communicate by
'backscattering' existing wireless signals.
RF-powered computers are small devices that compute and communicate using only the power that they harvest from RF signals.
The
router used in the tests sent out radio waves which were then converted
into a direct current voltage using what's known as a 'rectifier.'
This is similar to how solar panels convert light energy into electrical energy.
A
DC-DC converter was then used to increase the voltage level of the
signal to match the requirements of the sensor or microcontroller.
Assistant
professor Gollakota's technology isn't the first to harvest power from
ambient RF sources, but it is the first that doesn't require a dedicated
gateway, such as an RFID reader to connect to the web.
Specifically, the team reuse existing Wi-Fi infrastructure to provide connectivity to these low-power devices.
And
since it uses ambient radio frequency signals that are already around
us, it doesn't require a dedicated power infrastructure.
The users in homes one to four said they 'did not perceive any noticeable difference in their user experience.'
The
user in home five noted a significant improvement in his page load
times and better experience on streaming sites including Hulu, Amazon
Prime and YouTube.
The
researchers explained, though, that this was primarily because home
five originally was using a cheap low-grade router with worse
specifications.
The user in home 6 noted a 'slight deterioration in her YouTube viewing experience for a 30-minute duration.'
But
the researchers found traffic dipped generally on the network during
this time, so suggested it was caused by outside sources.
In
terms of powering devices, the research showed the router could power a
battery-free camera placed up to 17 feet (5 metres) from the router,
with an image capture every 35 minutes.
The technology (illustrated) was first
showcased by researchers at Washington University in August but
engineer Shyam Gollakota recently demonstrated the prototype router at
the EmTech Digital conference. The router sends out radio waves which
are converted into a direct current voltage using a 'rectifier'
The users in homes one to four said
they 'did not perceive any noticeable difference in user experience.' In
terms of powering devices, the research showed the router could power a
battery-free camera (left) placed 17 feet (5 metres) from the router,
as well as a battery-free temperature sensor, and chargers (right)
It also powered a battery-free temperature sensor.
In the team's paper,
called 'Powering the next billion devices with Wi-Fi', the researchers
said: There is increasing interest in the Internet-of-Things where small
computing sensors and mobile devices are embedded in everyday objects
and environments.
'A key issue is how to power these devices as they become smaller and more numerous.
'We
introduce a novel far-field power delivery system using existing Wi-Fi
chipsets [and] do so while minimising the impact on Wi-Fi network
performance.
'We prototype the first battery-free temperature and camera sensors that are powered with Wi-Fi devices.
'We also demonstrate the feasibility of wirelessly recharging nickel–metal hydride and lithium-ion coin cell batteries.'
Eventually, the technology could lead to
networks of devices and sensors that send data by reflecting existing
signals to exchange information, without the need for batteries.
Last year, the researchers tested the
ambient backscatter technique with credit card-sized prototype devices
placed within several feet of each other. For each device the
researchers built antennas into ordinary circuit boards that flash an
LED light when receiving a communication signal from another device
For example, everyday objects could also be enabled with battery-free tags to communicate with each other.
For instance, a couch could use ambient backscatter to let the user know where house keys were left.
Smart sensors could be built and placed permanently inside any structure, then set to communicate with each other.
This
could include a bridge that monitors the health of the concrete and
steel, then sends an alert if one of the sensors picks up a hairline
crack.
Last
year, the researchers tested the ambient backscatter technique with
credit card-sized prototype devices placed within several feet of each
other.
For
each device the researchers built antennas into ordinary circuit boards
that flash an LED light when receiving a communication signal from
another device.
Groups
of the devices were tested in a variety of settings in the Seattle
area, including inside an apartment building, on a street corner and on
the top level of a parking garage.
These locations ranged from less than half a mile away from a TV tower to about 6.5 miles away.
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