Lifeboat Foundation

If you want to use one of today’s major VR headsets, whether the Oculus Rift, the HTC Vive, or the PS VR, you have to accept the fact that there will be an illusion-shattering cable that tethers you to the small supercomputer that’s powering your virtual world.

But researchers from MIT’s Computer Science and Artificial Intelligence Laboratory (CSAIL) may have a solution in MoVr, a wireless virtual reality system. Instead of using Wi-Fi or Bluetooth to transmit data, the research team’s MoVR system uses high-frequency millimeter wave radio to stream data from a computer to a headset wirelessly at dramatically faster speeds than traditional technology.

There have been a variety of approaches to solving this problem already. Smartphone-based headsets such as Google’s Daydream View and Samsung’s Gear VR allow for untethered VR by simply offloading the computational work directly to a phone inside the headset. Or the entire idea of VR backpacks, which allow for a more mobile VR experience by building a computer that’s more easily carried. But there are still a lot of limitations to either of these solutions.

Continue reading “MIT’s new method of radio transmission could one day make wireless VR a reality” »

How does one prevent hacking from a QC system? Easy, on board to QC first before others do.

Quantum computers have the potential to perform calculations faster than ever possible before, inviting a significant rethink in how we approach cyber security.

Given the amount of research being ploughed into this area, we are likely to see a commercially viable machine in the near future, so cryptographers and the cyber security industry in general should work to have a clear view on the implications way ahead of that achievement.

Continue reading “How will quantum computing impact security processes?” »

Telegram has announced the first winners of its bot competition. The BotPrize was announced in April and will see $1 million awarded to developers of the best Telegram bots submitted. The first winners come from the worlds of photo-editing, productivity, games, dating and finance.

Telegram is a messaging service with a focus on speed and security. Launched in 2013, it is cloud-based, meaning that user content syncs instantly across the platforms on which the service can be used, including PC, Mac, Linux, Android, iOS and Windows Phone.

The firm’s BotPrize will help to increase the number of bots available on the service and accelerate the speed with which the number is increased. For the uninitiated, bots are effectively apps in themselves with which users can interact via messaging. They typically run inside messaging apps such as Facebook Messenger or, in this instance, Telegram.

Whenever cybersecurity is discussed, the topic of biometric authentication rises alongside it as a better, more effective, more secure method of security. But is it? Do biometrics actually provide a safer way to complete purchase transactions online?

“Biometrics are a device-specific authentication method,” said Madeline Aufseeser, CEO of online fraud prevention company Tender Armor, of the ways biometric authentication is presently used to secure a digital purchase transaction (as opposed to logging into a bank’s web site, to view an account or transfer money). “Typically the same biometric method does not work across multiple purchasing channels today. The fingerprint used to make a purchase with a smartphone cannot necessarily be used to authenticate a phone order purchase or purchase made with a computer. When you confirm [a purchase transaction] with your fingerprint on a smartphone, all that’s saying is that’s the same fingerprint that’s allowed to use this phone, or the specific application on the phone. Because the fingerprint is only resident and stored on the phone, the phone is authenticating itself, not the cardholder conducting the transaction.”

This sounds a little odd compared to what we might have heard about the capabilities of biometrics previously, mainly because it goes against a core assumption: that a biometric identifier (like a fingerprint) goes with transactional data, from the phone or device, to the payment processor, to the merchant.

Continue reading “Biometric Security Gains Popularity, But Is Far from Foolproof” »

With the phone, predictions now feel relatively easy. But we’re setting off on our next five years, and we’re looking beyond the phone. What happens next? And what does it mean for how we live in the future? For our anniversary, we asked 10 of the smartest, most interesting, most influential people we know to describe our lives in 2021 — and the many ways technology, culture, science, and transportation will change. We’ll be running these interviews all through November, and they paint an ambitious, dynamic vision of the future.

We’ll discuss how in the near future, many Americans may never drive again. We’ll talk to groundbreaking scientists about CRISPR, a revolutionary method of editing genes that’s already led to incredible breakthroughs. We’ll see how for many employees, technology may make geography irrelevant, and how social media will usher in a new age of social activism. More women will finally find their rightful place in boardrooms, and by 2021, artificial and human intelligence will exist in something called “symbiotic autonomy.”

It’s tempting to look backwards on an anniversary. But The Verge is about looking ahead, and we would much rather spend our fifth birthday imagining the incredible (and occasionally terrifying) promise of the future. We’ve collected some excellent guides to help us along the way — we hope you join us.

My suggestion to FB; learn from Microsoft.

We dug through 50+ job postings and new hire resumes looking for the truth.

In the future, circuits and systems modelled on human brains could end up in everything from supercomputers to everyday smartphones.

I have often talked about the Many-Worlds or Everett approach to quantum mechanics — here’s an explanatory video, an excerpt from From Eternity to Here, and slides from a talk. But I don’t think I’ve ever explained as persuasively as possible why I think it’s the right approach. So that’s what I’m going to try to do here. Although to be honest right off the bat, I’m actually going to tackle a slightly easier problem: explaining why the many-worlds approach is not completely insane, and indeed quite natural. The harder part is explaining why it actually works, which I’ll get to in another post.

Any discussion of Everettian quantum mechanics (“EQM”) comes with the baggage of pre-conceived notions. People have heard of it before, and have instinctive reactions to it, in a way that they don’t have to (for example) effective field theory. Hell, there is even an app, universe splitter, that lets you create new universes from your iPhone. (Seriously.) So we need to start by separating the silly objections to EQM from the serious worries.

The basic silly objection is that EQM postulates too many universes. In quantum mechanics, we can’t deterministically predict the outcomes of measurements. In EQM, that is dealt with by saying that every measurement outcome “happens,” but each in a different “universe” or “world.” Say we think of Schrödinger’s Cat: a sealed box inside of which we have a cat in a quantum superposition of “awake” and “asleep.” (No reason to kill the cat unnecessarily.) Textbook quantum mechanics says that opening the box and observing the cat “collapses the wave function” into one of two possible measurement outcomes, awake or asleep. Everett, by contrast, says that the universe splits in two: in one the cat is awake, and in the other the cat is asleep. Once split, the universes go their own ways, never to interact with each other again.

Continue reading “Why the Many-Worlds Formulation of Quantum Mechanics Is Probably Correct” »

Using ultrafast laser flashes, physicists from the Max Planck Institute have generated the fastest electric current that has ever been measured inside a solid material.

In the field of electronics, the principle ‘the smaller, the better’ applies. Some building blocks of computers or mobile phones, however, have become nearly as small today as only a few atoms. It is therefore hardly possible to reduce them any further.

Another factor for the performance of electronic devices is the speed at which electric currents oscillate. Scientists at the Max Planck Institute of Quantum Optics have now created electric currents inside solids which exceed the frequency of visible light by more than ten times They made electrons in silicon dioxide oscillate with ultrafast laser pulses. The conductivity of the material which is typically used as an insulator was increased by more than 19 orders of magnitude.

Continue reading “Scientists Generate the Fastest Electric Current Ever Measured Inside a Solid Material” »