Imagine you and a group of friends are at the peak of a mountain after a long hike. It’s sunset and the sky is alight; you want to take a photo. You pull out your smartphone, but instead of flipping it around to take a long-armed selfie, you unclip a tiny drone from the back of your phone, make it hover at the perfect height and snap a series of photos, no extendo-arms required.
Prosthetics have improved my leaps and bounds over the past century and we’ve reached a point where someone with an artificial limb is often just as capable (and in some cases even more capable) than a person with their natural arms and legs. Still, prosthetics have long fell short in one very important aspect, which is the sense of touch afforded by human skin. That could all be changing thanks to an incredible breakthrough that has provided a woman with a bionic hand that can actually feel.
Almerina Mascarello lost her left hand and part of her forearm in an accident more than two decades ago, and was chosen as one of the test subjects for a new type of prosthetic that relays the feeling of touch to the wearer. Remarkably, it seems to work brilliantly.
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Japanese RIKEN researchers are trying to adapt existing the silicon metal–oxide–semiconductor field-effect transistors (MOSFETs) to integrate qubits with current electronics, offering the potential for scaling up quantum devices and bringing quantum computing closer to becoming a reality.
Keiji Ono and colleagues from the RIKEN Center for Emergent Matter Science and the Toshiba Corporation in Japan, in collaboration with researchers from the United States, are investigating the properties of qubits produced by imperfections or defects in silicon MOSFETs. In particular, they are exploring their potential for developing quantum computing devices that are compatible with current manufacturing technologies.
“Companies like IBM and Google are developing quantum computers that use superconductors,” explains Ono. “In contrast, we are attempting to develop a quantum computer based on the silicon manufacturing techniques currently used to make computers and smart phones. The advantage of this approach is that it can leverage existing industrial knowledge and technology.”
Remember when Microsoft was actually aspiring to be mobile phone players? It seems like yesterday—but actually it was not so long ago. With the rise of the iPhone and flashy Android launches, the world got used to unsightly stats showing the Windows Phone dip.
While its drop of market share became evident, there is keen interest in whether or not Microsoft has ambitions as a comeback kid, not with a Windows Phone but with something now being rumored by watchers as a “Surface Phone”.
That probably explains why the “Hinge with free-stop function” patent filed this year has drawn a lot of interest among tech watchers when it surfaced on the World Intellectual Property Organization (WIPO) website.
If you’re like most of our readers, you’re probably reading this right now on your mobile, which means there’s also a chance you’re reading it on a broken, fragmented phone screen.
Luckily, the days of squinting at cracked phone displays like this could soon be over, thanks to a team of Japanese scientists who have developed a new kind of self-healing glass that fuses itself back together, simply by pressure being applied.
The self-healing polymer, created by researchers at the University of Tokyo, was initially discovered by accident while they were studying new adhesives.
IN AN AGE of nonstop breaches and hacks, getting a handle on your own digital security matters more than ever. But everyone has their own threat model—a set of concerns unique to themselves. The average smartphone user doesn’t need to know what a Faraday cage is; an NSA contractor probably already has a good grasp of security basics. (Or … do they?) In this guide, we’ve included a few ways to improve your online security posture based on those different levels of risk. These won’t prevent the next megabreach or banish ransomware from the earth. They’re not all-encompassing. But they’ll help get you in the mindset of the types of steps you should be taking based on your particular situation. And they’ll help ensure that the next time you read one of those paralyzing headlines, it doesn’t apply to you.
In an age of nonstop breaches and hacks, getting a handle on your own digital security matters more than ever. But everyone has their own threat model—a set of concerns unique to themselves. The average smartphone user doesn’t need to know what a Faraday cage is; an NSA contractor probably already has a good grasp of security basics. (Or … do they?) In this guide, we’ve included a few ways to improve your online security posture based on those different levels of risk. These won’t prevent the next megabreach or banish ransomware from the earth. They’re not all-encompassing. But they’ll help get you in the mindset of the types of steps you should be taking based on your particular situation. And they’ll help ensure that the next time you read one of those paralyzing headlines, it doesn’t apply to you.
There are a lot of people in the world that need glasses on a daily basis. Despite their often expensive price tag, they do little more than correct poor eyesight. Let Glass updates glasses for the 21st century by integrating them with smart home connectivity.
While maintaining a slim form factor, Let Glass features audio entertainment, telephone communication, and voice interaction. Using Alexa and a built-in microphone, these frames allow users to control their smartphones without fumbling through their pockets. Simply tapping the legs of the smart glasses activate remote control functions, while voice commands handle everything else. In addition to Amazon Alexa, Apple Siri and Google Now are also supported.
Keeping with a traditional appearance, audio is produced using bone conduction technology. Instead of a speaker, the glasses vibrate the small bones in the ear to produce sound. This also keeps ears open to other noises, ensuring users remain aware of their surroundings. This allows users to listen to music, track activity, use voice navigation, call a friend, and more.
