VOICE HACKERS WILL SOON HAVE A FREE WAY INTO YOUR TECHNOLOGY

Voice-activated technology is so vulnerable to attack that users should immediately disable speech recognition on all their devices, a security researcher at AVG has warned.
Yuval Ben-Itzhak, chief technology officer at the anti-virus company, has carried out several experiments which revealed the new techniques hackers might use to gain control of voice-controlled devices.
He made the ominous prediction that a “thief outside the door” could take control of gadgets such as smart televisions or laptops from outside a target’s home, potentially burgling them without even smashing a window.
The vulnerability of technology which uses voice commands is likely to become an important issue in the coming years, as smartwatches and connected home devices grow in popularity and the technology becomes commonplace.
His warning presages a future where voice hackers use recorded or synthesized speech commands to bypass security mechanisms. But this scary reality is not as far away as it might seem, as security researchers have already managed to trick Siri into letting them bypass the lock screen on an iPhone and post Facebook messages, access call history, send text messages and fire off emails.
“Microphones should be disabled immediately and our current recommendation is that the user switch off features [involving voice commands],” he said in a phone interview with Forbes. “At the moment, leaving biometric technology as it is today is like leaving a computer without a password and just allowing anyone to walk by, click and take an action.
“We realized there is something very basic here that everyone seems to have forgotten: authentication. If you have a smart TV at home, for instance, it will respond to a synthesized voice as well as yours.”
His team has conducted several experiments which give a clue as to how hackers might hijack voice controlled devices. In the first, the researchers designed a game for Android which was able to recite a voice command which ordered the personal assistant Google GOOGL -0.1% Now to send an email from the same device.
“If you played Google Now a recording of a voice, you could easily make it send a message to all your contacts and say: I’m broke, I need money,” he claimed.
In a further experiment involving another biometric form of identification, he designed an application which responded to the accelerometer in a phone and dialed up a premium rate number when the phone was in motion. When it came to rest, the call would immediately cut off. This could potentially raise significant sums of money for a thief before the hack was even noticed.
These sound like relatively innocuous crimes, but are likely to just be the first of many targets for the voice hackers.
“There is already voice recognition software in a car,”  Ben-Itzhak added. “Just imagine what could happen if someone targeted that.”
AVG does not have specific plans to release software to guard against voice hacking. Indeed, Ben-Itzhak claimed that few vendors were tackling the problem, even though it represented something of an open goal to hackers.
“We haven’t seen this in the wild yet,” he said. “But it is something that is pretty easy to take advantage off.”
One device which is sure to rely on voice commands is the Apple AAPL +1.03% Watch, which is expected to use a modified version of Siri. In the coming years, we are expected to see voice recognition embedded in everything from light bulbs to refrigerators.
Just keep an ear out for the thief at the door.

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IPHONE 6 PLUS NOT SO BENDABLE AFTER ALL

The experts have weighed in — the iPhone 6 Plus is not so bendy after all.
Calling recent criticism of the new Apple product "highly unscientific," Consumer Reports decided to find out for itself just how pliable the device is.
The magazine ran what it called a "three-point flexural test" on the phone, and it passed with flying colors.

 

In the test, the smartphone did not start to "deform" until 90 pounds of pressure was applied to it. According to the watchdog magazine, Apple uses the same test and applies 55 pounds of pressure to make sure the device is strong.
"All the phones we tested showed themselves to be pretty tough," said the Consumer Reports study, published online Friday. "The iPhone 6 Plus, the more robust of the new iPhones in our testing, started to deform when we reached 90 pounds of force, and came apart with 110 pounds of force."

Videos of customers bending the iPhone 6 Plus went viral last week, even though Apple claimed only nine people oficially complained.

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TOYOTA'S NEW HYDROGEN POWERED CAR SOON TO HIT THE MARKET BY 2015

Toyota’s on the verge of finally bringing a hydrogen-powered car to market. The problem is that it promises a boring, if innovative, driving experience, for the price middle-aged men pay to have their toupees blown off.

Next year, Toyota will start selling the unimaginatively named FCV (to be fair, Honda had dibs on FCEV). The car will be able to drive 300 miles on nothing but hydrogen, with only water vapor as a byproduct. Hybrids and battery-powered electrics are hogging all the attention when it comes to alternatives to internal-combustion engines, but the German and Japanese automakers, especially Honda and Toyota, haven’t backed off the idea that the best route to a fossil fuel-free future is using fuel cells to combine hydrogen and oxygen to generate electricity, inside the car. Fuel-cell cars offer the range of a gas-powered car, and their tanks can be filled with compressed hydrogen in just a few minutes. No range anxiety, no waiting hours for your EV’s battery to charge.
FCEVs have plenty of shortcomings. Hydrogen fuel is available at only a handful of gas stations in the U.S., and the infrastructure for transporting it around the country hasn’t really been developed. The production of hydrogen can itself yield greenhouse gases, if it’s generated from natural gas. The cars are frightfully expensive and the fuel is no cheaper than gasoline. But Toyota’s serious about the technology. It has spent 20 years on this program and made a lot of progress. From one generation of test vehicles to the current platform, it cut costs by 95 percent, reduced the size of the fuel cell, and developed tanks made of carbon fiber that improve capacity and can be designed to fit any car body. To make filling up the hydrogen tanks practical, Toyota’s part of a state-funded, $200 million effort to build a network of fueling stations around the Bay Area and Los Angeles, with a few in between. That will help build out the infrastructure and encourage people to buy the cars. It doesn’t do anything for the cost of the fuel itself, which by Toyota’s estimates is as expensive as gasoline.

Last week, I met up with Jared Farnsworth, an engineer with Toyota’s advanced power train group, to gawk at the FCV and drive the test “mule,” the camouflaged Lexus HS that’s been fitted with a system very similar to the one that will be in the production car. Under the hood is a fuel cell roughly the size of a suitcase, pulling hydrogen from two tanks each a bit bigger than what you take scuba diving. Total power output is roughly 100 kilowatts.
I drove the mule for just about 15 minutes around downtown San Francisco, hardly enough to form a detailed judgement, but came away with one impression: This thing, like other FCEVs, is completely unremarkable. The torque is a bit better than your standard internal combustion engine car. There’s no noise, which is nice. I didn’t get the chance to floor it, but the lackluster 0 to 60 mph time of under 10 seconds promised by Toyota sounds about right. All in all, it drives like an underpowered electric car.

The FCV doing cold weather testing in Yellowknife, Canada. Toyota

A High Price for Meh

Toyota hasn’t released U.S. pricing for the FCV, but it will charge Japanese customers $69,000. A few years ago, it said it was aiming to deliver the 2015 car for $50,000, which is still a lot of money for a car that won’t save you any money on fuel, can only be filled at select stations in California, and is barely more fun to drive than a Camry—whether or not you’re helping the planet breathe.
“There’s no doubt, that the success of this technology will depend less on the genius of the car, than on the ownership experience,” says Bob Carter, a Toyota senior vice president. “Cost in one thing, but convenience is another.” It’s a fair point, but the high price would hardly be an issue if the drive experience were more fulfilling. Tesla customers can justify the $71,070 base price and reduced range of the Model S because the battery-powered sedan is not only elegant, it’s one of the most thrilling and capable cars you can buy today. The most powerful version goes from 0 to 60 mph in 4.2 seconds with enough torque to imitate the space shuttle taking off.
The Toyota FCV has an edgy look to grab attention, especially for a four-door midsize sedan. Toyota’s design philosophy of “air into water” results in nice lines from the front to the rear. (Toyota isn’t showing off the interior just yet.) But the car is missing the performance to back up the fresh look and get people really excited about hydrogen.
Toyota may be right to say fuel cell cars have a place alongside their hybrid and battery-powered brethren in the roster of future technologies. The best way to prove it—or at least to get the public really interested in the idea—is to give us a hydrogen-powered car that really excites.
Fortunately, Farnsworth says cranking up the power of an FCEV would mostly be a question of increasing the number of plates in the fuel cell stack, which presumably comes with a few extra engineering challenges. Toyota’s already working with Hino Motors to make fuel cell-powered commercial vehicles, which require bigger power plants. Even better, it’s got an agreement with BMW to jointly develop a fuel cell system by 2020. BMW is very good at making cars that don’t suck (or bore), so we’ve got high hopes.

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SAY HI TO STELLA (THE SOLAR POWERED CAR) THAT DRIVES 500 MILES ON A SINGLE CHARGE!!

MEET STELLA!!

The lightweight, wedge-shaped electric car charges itself with solar cells 

It was built at Eindhoven University of Technology in Holland

It travels 500 miles (800km) on a single charge at speeds of 80mph (130km/h)

This distance is increased if the sun is shining thanks to panels on the roof

Car also features a tablet that shows driver when traffic lights will change

And Stella's steering wheel expands if you drive too fast

Stella is a prototype, but recently drove from Los Angeles to San Francisco

 Stella is a solar-powered family car has completed a drive from Los Angeles to San Francisco fuelled entirely by sunshine - a journey covering almost 385 miles (619km).Stella can travel up to 500 miles (800 km) on a single charge, clocking speeds of up to 80mph (130 km). The prototype 4 seater car has solar cells on its roof to provide power while driving, and it boasts of a tablet that tracks traffic light. The vehicle was created by a group called Solar Tam Eindhoven, based at Eindhoven University of Technology in the Netherlands.Stella's recent journey took it up California's scenic Pacific Coast Highway into the centre of L.A. and the creators of Stella hope their vehicle might one day enter mass production, and become a common sight on roads.

The 1.5-kilowatt array of solar panels on top of the car, which cost about £2,600 ($4,260) to produce, supply power to the car's lithium ion battery.

At the back of the car, the panels can be lifted up to reveal a boot, and according toTakePart, other novelties include a steering wheel that expands when a user drives too fast, and contracts when they drive too slow. 

It weighs 855lbs (390kg) and is 15ft (4.6 metres) long, while the body of the vehicle is made of carbon fibre. Its aerodynamic shape also helps to increase its driving range.But the car is less than 4ft (1.2 metres) tall, so getting in is a bit of a squeeze.Stella can even communicate with other cars; during an example, it relayed traffic information to a Tesla Model S nearby.

And this extends to traffic lights as well - a tablet screen in the car will tell the driver how long until a light up ahead turns red or green.

The car also features smart technology, including a tablet that shows the driver when traffic lights will change colour (pictured). It can also 'talk' to other cars

At the back of the car, (pictured) the panels can be lifted up to reveal a boot. Stella weighs 855lbs (390kg) and is 15ft (4.6 metres) long, while the body of the vehicle is made of carbon fibre. Its aerodynamic shape also helps to increase its driving range. But it is less than 4ft (1.2 metres) tall, so getting in is a bit of a squeeze

'It was great to see all the people looking at us; hurrying to get their smartphones out to get pictures while we were driving,' said Lex Hoefsloot, manager of Solar Team Eindhoven after the car had undertaken its drive from Los Angeles to San Francisco. 'I think we caused some traffic jams and we were worried some drivers might run into us while trying to take pictures.'

Hoefsloot is one of the students at Eindhoven University of Technology who designed and built Stella in what grew into a school-wide project that won a World Solar Car challenge race across Australia in 2013. Stella launched a US tour in Detroit at the Intelligent Transportation Society World Congress in early September. The team drove to San Francisco to join sponsor NXP Semiconductors of The Netherlands in an event focused on a future in which roads are made safer and air pollution reduced by cars that 'talk' to one another as well as traffic signals.

'We think it is possible to make these cars and have them in a showroom in five to 10 years, but it is a big dream and something we have to really work on,' said Hoefsloot. 

The technology in Stella is not new and if the solar cars were mass-produced like gas-guzzling models they could be similarly affordable, according to the student.

But big auto-makers have had little contact with the team because 'they think it is too far-fetched,' Hoefsloot told AFP. 'We think otherwise, of course,' he said. 'It is the first family car that is powered by solar energy, it just doesn't have a family yet!.' 

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JAPANESE COMPANY PLANS CONSTRUCTION OF SPACE ELEVATOR BY 2050!

Researchers heading into space in the not-too-distant future could be travelling by elevator rather than rocket if Japanese construction giant Obayashi Corporation has its way. The company announced two years ago that it has the capacity to build a space elevator -- and have it up and running by the year 2050.
Speaking to the Australian Broadcasting Corporation this month, the company said that the elevator would reach 96,000km (59,652 miles) into space (for reference, space lies beyond the Kármán Line, at an altitude of 100km, the International Space Station is 330km, and the moon is 384,400km from Earth), and use robotic cars powered by magnetic linear motors (maglev, as seen in high-speed rail lines around Asia and Europe) to ferry cargo and humans to a new space station.
All this, the company said, can be achieved because of carbon nanotechnology.

"The tensile strength is almost a hundred times stronger than steel cable so it's possible," said Obayashi research and development manager Yoji Ishikawa. "Right now we can't make the cable long enough. We can only make 3-centimetre-long nanotubes but we need much more... we think by 2030 we'll be able to do it."
Teams around Japan are working on logistics problems associated with the elevator. A team at Kanagawa University, for example, is working on the problems associated with the robotic cars: how to ascend at varying altitudes and how to brake. If the project is successful, it could massively cut the cost and danger associated with space trips: cargo usually costs around $22,000 per kilogram via shuttle; using Obayashi's space elevator, the cost would be closer to $200, the company said.
Obayashi is not the only company working on the feasibility of a space elevator, which could provide cheap solar power, provide a hub for space exploration and boost space tourism. In 2012, former NASA contractor Michael Laine launched a Kickstarter to raise funds to research the feasibility of a lunar space elevator, raising $110,353.
Building a space elevator, however, will likely require an international effort, and the International Space Elevator Consortium is already attempting to coordinate efforts.
"I don't think one company can make it, we'll need an international organisation to make this big project," Ishikawa agreed.

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2015 TOYOTA CAMRY REVIEW

Good day all,today on DatingNature,we will talk about the Toyota Camry 2015 model..every car has its definitive year. Whether it be the Chevrolet Corvette, the Ford Mustang, or yes, even the ubiquitous Toyota Camry, 10.2 million of which have been sold since 1983, every car has its year. For the Camry, that year was 1992. With son-of-Lexus styling, a clear sense of purpose and a parent company that had hit its stride as the purveyor of faultlessly reliable family transportation devices, the Camry got its legs in 1992. It's a car that even your mom is likely to remember, even if she never owned one herself.
The Camry you see here represents the closest Toyota has come to emulating the magic formula that made the 1992 model the stuff of legends. Compared to the 2014 model, some 2000 of the car's 6,000 parts are new, most of them involving things you can see or touch (on the outside, for example, only the roof carries over from 2014).
It's not a full redesign, but nevertheless it's a stunning development considering the predecessor upon which it's based only survived two model years. That's a testament to both the hyper-competitive nature of the family sedan segment and the lukewarm critical response that the outgoing car garnered. But that's in the past now – after driving this 2015 model, we suspect the new car's changes will be thorough enough to continue pulling in new customers by the hundreds of thousands each year for the foreseeable future.

Camry's sculpted and elongated body gives it a sense of grace it hasn't had since 1992.

For starters, it looks great. Photos perhaps overemphasize the gaping, Avalon-inspired maw, but the Camry's sculpted and elongated body – 1.7 inches longer than its predecessor – gives it a sense of grace it hasn't had since the aforementioned 1992 model. Swoopy new headlamps walk the line between pretty and predatory, and hash marks running down the cheeks containing LED running lamps on some models, add a bit of edge. Out back is a remarkably clean decklid/bumper situation, including a tasteful spoiler on certain models.
The new-for-15 XSE model (seen here in V6 form) brings monochromatic paint, blacked-out exterior details, and sexy 18-inch black and machined wheels (compared to 16-inch steel wheels/covers on LE models and 17-inchers on LE and SE models). It's a look that attempts to close in on the Mazda6 in sex appeal, yet isn't so radical that your grandma won't get inside when it's time to take her to church. If there's a weak spot in the design, it's the C-pillar garnish that pretends to be a window but isn't; still, even that deserves some of the credit for making this car look a bit more like the '92.

On the inside, nearly every surface with which the driver or passengers interact has been changed. It's still conservative, yet more upscale.

On the inside, nearly every surface with which the driver or passengers interact has been changed – nothing radical, but if we were to put it in, say, hotel terms, the Camry interior has gone from Courtyard By Marriott to, well, Marriott – still conservative, yet more upscale. The high H-point seats feature the now-mandatory contrast stitching, and you'll find a bit more soft (or soft-ish) touch stuff on the dash and door panels. Color schemes correspond closely to trim level – rental-grade grays for the appliance-like LE; sportier and more metallic-heavy with the SE (now four-cylinder only); sinister with the new XSE grade, with all-black leatherette/faux suede upholstery and red stitching; leather-lined and luxurious with the top-dog XLE models. The latter two trims also get rear seat air vents and dual-zone climate controls inside, as well as full LED headlamps on the outside.
The new Camry also steps up its electronics, starting with Optitron gauge clusters on SE models and above, and nice, three-dimensional primary dials flanking a new high-definition info screen. The XSE and XLE V6 models get charging ports behind a door in the dashboard, as well as larger touchscreens (7.0 inches vs. 6.1 on the rest) for their app-based Entune infotainment systems. Safety options come in the form of a pre-collision system, automatic high beams and blind spot monitoring with rear cross-traffic alert.

Toyota engineers retuned the Camry's shocks and springs for more responsiveness without killing the velvety ride quality for which the Camry is known.

Under the skin, there's not as much new stuff, but what has been changed is all vastly appreciated. As with many of Toyota's redesigned and refreshed vehicles, including the Yaris and Sienna, which we also drove this week in Hawaii (stay tuned), the Camry gets added structural reinforcements, including many more spot welds. This in turn has allowed Toyota engineers to retune the Camry's shocks and springs for more responsiveness without killing the velvety ride quality for which the Camry, and most Toyotas, for that matter, are known. A 0.4-inch increase in track gives all models a bit more of a planted stance.
The pre-production Camry models we drove on the mostly benign roads on the Big Island of Hawaii proved more responsive to inputs and less wobbly in corners than their predecessors, and the aforementioned XSE model is almost (though not quite) fun. We reviewed the Hybrid model separately, but from this author's perspective, it seems that all Camry models are even quieter than the cars that came before them.
One particular revelation involves the Camry's XSE's brakes, which are remarkably well tuned, thanks in part to a new two-stage master cylinder. Initial bite is crisp and response is linear all the way down the pedal travel. Stopping the car had us conjuring thoughts of the Mazda6, though with 60 to 100 pounds more weight than in 2014, the 2015 Camry still doesn't feel as light as the Mazda in any form. Also, if you want the most Germanic steering (i.e. with a bit of heft and a modicum of tactility through the wheel) point your browser to the XSE model and don't look at anything else.

With 268 hp and 248 lb-ft, the 3.5-liter V6 is strong but course. And if those V6 stats seem familiar, it's because they haven't changed since the Bush administration.

If the Camry is a letdown in any particular respect, it's that the gas powertrains are virtually 100-percent carryover from before, and not surprisingly, they feel about as scintillating (which is to say not very) as ever. The standard 2.5-liter inline four-cylinder makes decent power – 178 horsepower at 6,000 rpm and 170 pound-feet of torque at 4,100 rpm – though it requires one to wind it out pretty good to get to it, and the six-speed automatic is none too playful a dance partner, even using the SE's manual shift paddles.
With 268 hp at 6,200 rpm and 248 lb-ft of torque at 4,700 rpm, the 3.5-liter V6 available only with XLE and XSE models is much stronger than the four-pot, of course, but its coarseness at high revs makes it none too enjoyable to access that power. And if those V6 stats seem familiar, it's because they haven't changed since the Bush administration. Therefore we're relatively certain that the V6 should be able to get the Camry to 60 mph in about 6.5 seconds, because that's what it's always done. The four-pot will probably take about a second or longer to do the same trick. And finally, EPA fuel economy estimates remain the same as before, at 25 miles per gallon city, 35 mpg highway for the four-cylinder and 21/31 for the V6.

After driving the 2015 Camry, we'd say that this Toyota's spot at the top of the charts seems as secure as ever.

At $23,895 and $24,665, respectively, Camry LE and SE models come in at virtually the same price as their predecessors, while the $26,975 XLE brings about $1,200 more equipment into 2015 for just $340 more than before. The XSE is priced exactly the same as the XLE; both are expected to run about 11 percent of the model mix, according to Toyota.
The stakes couldn't be higher for Toyota when it comes to this car's success. For the last 12 years, the sales crown has been Camry's to lose, and the competition from Honda, Mazda, Kia, Hyundai, Chrysler, Ford and others – to say nothing of compact and midsize crossovers – has gotten stronger than ever. But after driving the 2015 Camry, we'd say that this Toyota's spot at the top of the charts seems as secure as ever.

News Source: Copyright 2014 Steve Siler / AOL

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TOSHIBA MOST LIKELY TO AID ASUS

A recent decision by Japan’s Toshiba Corp to exit certain consumer laptop markets is likely to benefit Taiwan’s Asustek Computer Inc because of their similar product positions, brokerage Morgan Stanley said on Sunday.
Following Sony’s disposal of its Vaio PC business and Samsung’s scaling down of its notebook business, Toshiba announced on Thursday that it would accelerate the restructuring of its PC business and withdraw from certain consumer markets.
The Japanese electronics conglomerate said it would also cut 900 jobs during the current fiscal year, which was expected to save the company more than ￥20 billion (US$184 million) in fixed costs compared with the previous year.
“We see Asustek as the major beneficiary if Toshiba withdraws from some consumer markets [because] both have consumer products in similar price ranges,” Grace Chen, a Morgan Stanley analyst in Taipei, said in a note to clients.
In comparison, Lenovo Group  and Acer Inc are targeting the lower-end consumer notebook segment, she said.
Citing data from research firm IDC, Chen said Toshiba’s PC business covers mainly notebooks, which declined by an annual 15 percent last year to 14 million units, holding an 8 percent share of the global market.
Asustek, meanwhile, shipped 19 million notebooks last year, she added.
“Asustek’s third-quarter notebook shipments are tracking slightly ahead of our forecast and we expect its fourth-quarter shipments to outperform its peers, as it will launch new products,” Chen said.
Acer founder Stan Shih on sunday said at a press briefing that Toshiba’s restructuring plan is a “normal” phenomenon in the PC industry that allows PC companies to reflect on their decisions and learn more about the industry’s dynamics.
The PC industry needs to change its role after more than 30 years in existence and it also needs new strategies to deal with the shrinking market, Shih said on the sidelines of a awards ceremony for an Acer comic competition, a promotional event for its cloud services.

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.d

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpufH

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.

Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise. Pictured here is the zinc oxide used in the device.

The team used the key properties of zinc oxide, a material that when squashed or stretched creates a voltage by converting energy from motion into electrical energy, in the form of nanorods.
The nanorods can be coated onto various surfaces in different locations making the energy harvesting versatile.
When this surface is squashed or stretched, the nanorods then generate a high voltage.
The nanorods respond to vibration and movement created by everyday sound, such as our voices.
Electrical contacts on both sides of the rods are then used to harvest the voltage to charge a phone.
In order to make it possible to produce these nanogenerators at scale, the scientists found innovative ways to cut costs in the production process.
Firstly, they developed a process whereby they could spray on the nanorod chemicals – almost like nanorod graffiti – to cover a plastic sheet in a layer of zinc oxide.
When put into a mixture of chemicals and heated to just 90°C, the nanorods grew all over the surface of the sheet.
Secondly, gold is traditionally used as an electrical contact, but the team were able to produce a method of using cheap and cheerful aluminium foil instead.
The final device is the same size as a Nokia Lumia 925 and generates five volts, which is enough to charge a phone.
‘Being able to keep mobile devices working for longer, or do away with batteries completely by tapping into the stray energy that is all around us is an exciting concept,’ said Dr Joe Briscoe from QMUL.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.

Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise. Pictured here is the zinc oxide used in the device.

The team used the key properties of zinc oxide, a material that when squashed or stretched creates a voltage by converting energy from motion into electrical energy, in the form of nanorods.
The nanorods can be coated onto various surfaces in different locations making the energy harvesting versatile.
When this surface is squashed or stretched, the nanorods then generate a high voltage.
The nanorods respond to vibration and movement created by everyday sound, such as our voices.
Electrical contacts on both sides of the rods are then used to harvest the voltage to charge a phone.
In order to make it possible to produce these nanogenerators at scale, the scientists found innovative ways to cut costs in the production process.
Firstly, they developed a process whereby they could spray on the nanorod chemicals – almost like nanorod graffiti – to cover a plastic sheet in a layer of zinc oxide.
When put into a mixture of chemicals and heated to just 90°C, the nanorods grew all over the surface of the sheet.
Secondly, gold is traditionally used as an electrical contact, but the team were able to produce a method of using cheap and cheerful aluminium foil instead.
The final device is the same size as a Nokia Lumia 925 and generates five volts, which is enough to charge a phone.
‘Being able to keep mobile devices working for longer, or do away with batteries completely by tapping into the stray energy that is all around us is an exciting concept,’ said Dr Joe Briscoe from QMUL.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.

Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise. Pictured here is the zinc oxide used in the device.

The team used the key properties of zinc oxide, a material that when squashed or stretched creates a voltage by converting energy from motion into electrical energy, in the form of nanorods.
The nanorods can be coated onto various surfaces in different locations making the energy harvesting versatile.
When this surface is squashed or stretched, the nanorods then generate a high voltage.
The nanorods respond to vibration and movement created by everyday sound, such as our voices.
Electrical contacts on both sides of the rods are then used to harvest the voltage to charge a phone.
In order to make it possible to produce these nanogenerators at scale, the scientists found innovative ways to cut costs in the production process.
Firstly, they developed a process whereby they could spray on the nanorod chemicals – almost like nanorod graffiti – to cover a plastic sheet in a layer of zinc oxide.
When put into a mixture of chemicals and heated to just 90°C, the nanorods grew all over the surface of the sheet.
Secondly, gold is traditionally used as an electrical contact, but the team were able to produce a method of using cheap and cheerful aluminium foil instead.
The final device is the same size as a Nokia Lumia 925 and generates five volts, which is enough to charge a phone.
‘Being able to keep mobile devices working for longer, or do away with batteries completely by tapping into the stray energy that is all around us is an exciting concept,’ said Dr Joe Briscoe from QMUL.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.

Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise. Pictured here is the zinc oxide used in the device.

The team used the key properties of zinc oxide, a material that when squashed or stretched creates a voltage by converting energy from motion into electrical energy, in the form of nanorods.
The nanorods can be coated onto various surfaces in different locations making the energy harvesting versatile.
When this surface is squashed or stretched, the nanorods then generate a high voltage.
The nanorods respond to vibration and movement created by everyday sound, such as our voices.
Electrical contacts on both sides of the rods are then used to harvest the voltage to charge a phone.
In order to make it possible to produce these nanogenerators at scale, the scientists found innovative ways to cut costs in the production process.
Firstly, they developed a process whereby they could spray on the nanorod chemicals – almost like nanorod graffiti – to cover a plastic sheet in a layer of zinc oxide.
When put into a mixture of chemicals and heated to just 90°C, the nanorods grew all over the surface of the sheet.
Secondly, gold is traditionally used as an electrical contact, but the team were able to produce a method of using cheap and cheerful aluminium foil instead.
The final device is the same size as a Nokia Lumia 925 and generates five volts, which is enough to charge a phone.
‘Being able to keep mobile devices working for longer, or do away with batteries completely by tapping into the stray energy that is all around us is an exciting concept,’ said Dr Joe Briscoe from QMUL.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.

Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise. Pictured here is the zinc oxide used in the device.

The team used the key properties of zinc oxide, a material that when squashed or stretched creates a voltage by converting energy from motion into electrical energy, in the form of nanorods.
The nanorods can be coated onto various surfaces in different locations making the energy harvesting versatile.
When this surface is squashed or stretched, the nanorods then generate a high voltage.
The nanorods respond to vibration and movement created by everyday sound, such as our voices.
Electrical contacts on both sides of the rods are then used to harvest the voltage to charge a phone.
In order to make it possible to produce these nanogenerators at scale, the scientists found innovative ways to cut costs in the production process.
Firstly, they developed a process whereby they could spray on the nanorod chemicals – almost like nanorod graffiti – to cover a plastic sheet in a layer of zinc oxide.
When put into a mixture of chemicals and heated to just 90°C, the nanorods grew all over the surface of the sheet.
Secondly, gold is traditionally used as an electrical contact, but the team were able to produce a method of using cheap and cheerful aluminium foil instead.
The final device is the same size as a Nokia Lumia 925 and generates five volts, which is enough to charge a phone.
‘Being able to keep mobile devices working for longer, or do away with batteries completely by tapping into the stray energy that is all around us is an exciting concept,’ said Dr Joe Briscoe from QMUL.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.

Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise. Pictured here is the zinc oxide used in the device.

The team used the key properties of zinc oxide, a material that when squashed or stretched creates a voltage by converting energy from motion into electrical energy, in the form of nanorods.
The nanorods can be coated onto various surfaces in different locations making the energy harvesting versatile.
When this surface is squashed or stretched, the nanorods then generate a high voltage.
The nanorods respond to vibration and movement created by everyday sound, such as our voices.
Electrical contacts on both sides of the rods are then used to harvest the voltage to charge a phone.
In order to make it possible to produce these nanogenerators at scale, the scientists found innovative ways to cut costs in the production process.
Firstly, they developed a process whereby they could spray on the nanorod chemicals – almost like nanorod graffiti – to cover a plastic sheet in a layer of zinc oxide.
When put into a mixture of chemicals and heated to just 90°C, the nanorods grew all over the surface of the sheet.
Secondly, gold is traditionally used as an electrical contact, but the team were able to produce a method of using cheap and cheerful aluminium foil instead.
The final device is the same size as a Nokia Lumia 925 and generates five volts, which is enough to charge a phone.
‘Being able to keep mobile devices working for longer, or do away with batteries completely by tapping into the stray energy that is all around us is an exciting concept,’ said Dr Joe Briscoe from QMUL.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.

Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise. Pictured here is the zinc oxide used in the device.

The team used the key properties of zinc oxide, a material that when squashed or stretched creates a voltage by converting energy from motion into electrical energy, in the form of nanorods.
The nanorods can be coated onto various surfaces in different locations making the energy harvesting versatile.
When this surface is squashed or stretched, the nanorods then generate a high voltage.
The nanorods respond to vibration and movement created by everyday sound, such as our voices.
Electrical contacts on both sides of the rods are then used to harvest the voltage to charge a phone.
In order to make it possible to produce these nanogenerators at scale, the scientists found innovative ways to cut costs in the production process.
Firstly, they developed a process whereby they could spray on the nanorod chemicals – almost like nanorod graffiti – to cover a plastic sheet in a layer of zinc oxide.
When put into a mixture of chemicals and heated to just 90°C, the nanorods grew all over the surface of the sheet.
Secondly, gold is traditionally used as an electrical contact, but the team were able to produce a method of using cheap and cheerful aluminium foil instead.
The final device is the same size as a Nokia Lumia 925 and generates five volts, which is enough to charge a phone.
‘Being able to keep mobile devices working for longer, or do away with batteries completely by tapping into the stray energy that is all around us is an exciting concept,’ said Dr Joe Briscoe from QMUL.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.

Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise. Pictured here is the zinc oxide used in the device.

The team used the key properties of zinc oxide, a material that when squashed or stretched creates a voltage by converting energy from motion into electrical energy, in the form of nanorods.
The nanorods can be coated onto various surfaces in different locations making the energy harvesting versatile.
When this surface is squashed or stretched, the nanorods then generate a high voltage.
The nanorods respond to vibration and movement created by everyday sound, such as our voices.
Electrical contacts on both sides of the rods are then used to harvest the voltage to charge a phone.
In order to make it possible to produce these nanogenerators at scale, the scientists found innovative ways to cut costs in the production process.
Firstly, they developed a process whereby they could spray on the nanorod chemicals – almost like nanorod graffiti – to cover a plastic sheet in a layer of zinc oxide.
When put into a mixture of chemicals and heated to just 90°C, the nanorods grew all over the surface of the sheet.
Secondly, gold is traditionally used as an electrical contact, but the team were able to produce a method of using cheap and cheerful aluminium foil instead.
The final device is the same size as a Nokia Lumia 925 and generates five volts, which is enough to charge a phone.
‘Being able to keep mobile devices working for longer, or do away with batteries completely by tapping into the stray energy that is all around us is an exciting concept,’ said Dr Joe Briscoe from QMUL.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.

Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise. Pictured here is the zinc oxide used in the device.

The team used the key properties of zinc oxide, a material that when squashed or stretched creates a voltage by converting energy from motion into electrical energy, in the form of nanorods.
The nanorods can be coated onto various surfaces in different locations making the energy harvesting versatile.
When this surface is squashed or stretched, the nanorods then generate a high voltage.
The nanorods respond to vibration and movement created by everyday sound, such as our voices.
Electrical contacts on both sides of the rods are then used to harvest the voltage to charge a phone.
In order to make it possible to produce these nanogenerators at scale, the scientists found innovative ways to cut costs in the production process.
Firstly, they developed a process whereby they could spray on the nanorod chemicals – almost like nanorod graffiti – to cover a plastic sheet in a layer of zinc oxide.
When put into a mixture of chemicals and heated to just 90°C, the nanorods grew all over the surface of the sheet.
Secondly, gold is traditionally used as an electrical contact, but the team were able to produce a method of using cheap and cheerful aluminium foil instead.
The final device is the same size as a Nokia Lumia 925 and generates five volts, which is enough to charge a phone.
‘Being able to keep mobile devices working for longer, or do away with batteries completely by tapping into the stray energy that is all around us is an exciting concept,’ said Dr Joe Briscoe from QMUL.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.

Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise. Pictured here is the zinc oxide used in the device.

The team used the key properties of zinc oxide, a material that when squashed or stretched creates a voltage by converting energy from motion into electrical energy, in the form of nanorods.
The nanorods can be coated onto various surfaces in different locations making the energy harvesting versatile.
When this surface is squashed or stretched, the nanorods then generate a high voltage.
The nanorods respond to vibration and movement created by everyday sound, such as our voices.
Electrical contacts on both sides of the rods are then used to harvest the voltage to charge a phone.
In order to make it possible to produce these nanogenerators at scale, the scientists found innovative ways to cut costs in the production process.
Firstly, they developed a process whereby they could spray on the nanorod chemicals – almost like nanorod graffiti – to cover a plastic sheet in a layer of zinc oxide.
When put into a mixture of chemicals and heated to just 90°C, the nanorods grew all over the surface of the sheet.
Secondly, gold is traditionally used as an electrical contact, but the team were able to produce a method of using cheap and cheerful aluminium foil instead.
The final device is the same size as a Nokia Lumia 925 and generates five volts, which is enough to charge a phone.
‘Being able to keep mobile devices working for longer, or do away with batteries completely by tapping into the stray energy that is all around us is an exciting concept,’ said Dr Joe Briscoe from QMUL.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.

Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise. Pictured here is the zinc oxide used in the device.

The team used the key properties of zinc oxide, a material that when squashed or stretched creates a voltage by converting energy from motion into electrical energy, in the form of nanorods.
The nanorods can be coated onto various surfaces in different locations making the energy harvesting versatile.
When this surface is squashed or stretched, the nanorods then generate a high voltage.
The nanorods respond to vibration and movement created by everyday sound, such as our voices.
Electrical contacts on both sides of the rods are then used to harvest the voltage to charge a phone.
In order to make it possible to produce these nanogenerators at scale, the scientists found innovative ways to cut costs in the production process.
Firstly, they developed a process whereby they could spray on the nanorod chemicals – almost like nanorod graffiti – to cover a plastic sheet in a layer of zinc oxide.
When put into a mixture of chemicals and heated to just 90°C, the nanorods grew all over the surface of the sheet.
Secondly, gold is traditionally used as an electrical contact, but the team were able to produce a method of using cheap and cheerful aluminium foil instead.
The final device is the same size as a Nokia Lumia 925 and generates five volts, which is enough to charge a phone.
‘Being able to keep mobile devices working for longer, or do away with batteries completely by tapping into the stray energy that is all around us is an exciting concept,’ said Dr Joe Briscoe from QMUL.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

Gadget converts sound waves from speech into five volts of energy for your mobile.
As the class Governor of my department at Yaba college Of technology, It seems phone batteries always die at the same moment you need to make an important call like calling a Lecturer , before class or after class.
But while shouting at your mobile in frustration might seem pointless, a new gadget could soon mean your screams won’t be in vain.
Researchers in London have created a new technology that uses sound, such as chants at a football ground or chatter in a coffee shop, to charge up mobile phones.
Their prototype device, which is about the size of a mobile phone, uses zinc oxide to convert vibrations caused by sound into electricity.
The invention was inspired by previous research at Queen Mary University of London (QMUL), which found playing pop and rock music improved the performance of solar cells.
This was because the sound vibrations triggered the movement of material in the solar cell that caused it to improve efficiency by up to 40 per cent.
Developing this research further, Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise.

Nokia worked with the QMUL team to create an energy-harvesting prototype that could be used to charge a mobile phone using everyday background noise. Pictured here is the zinc oxide used in the device.

The team used the key properties of zinc oxide, a material that when squashed or stretched creates a voltage by converting energy from motion into electrical energy, in the form of nanorods.
The nanorods can be coated onto various surfaces in different locations making the energy harvesting versatile.
When this surface is squashed or stretched, the nanorods then generate a high voltage.
The nanorods respond to vibration and movement created by everyday sound, such as our voices.
Electrical contacts on both sides of the rods are then used to harvest the voltage to charge a phone.
In order to make it possible to produce these nanogenerators at scale, the scientists found innovative ways to cut costs in the production process.
Firstly, they developed a process whereby they could spray on the nanorod chemicals – almost like nanorod graffiti – to cover a plastic sheet in a layer of zinc oxide.
When put into a mixture of chemicals and heated to just 90°C, the nanorods grew all over the surface of the sheet.
Secondly, gold is traditionally used as an electrical contact, but the team were able to produce a method of using cheap and cheerful aluminium foil instead.
The final device is the same size as a Nokia Lumia 925 and generates five volts, which is enough to charge a phone.
‘Being able to keep mobile devices working for longer, or do away with batteries completely by tapping into the stray energy that is all around us is an exciting concept,’ said Dr Joe Briscoe from QMUL.
- See more at: http://www.naijaloaded.com.ng/2014/08/20/charge-phone-shouting-see-works/#sthash.oggLHMUe.dpuf

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