An employee pushes a trolley with a Vizio Inc. high-definition television (HDTV) at a Target Corp. store on Black Friday in Dallas, Texas, on Friday, Nov. 24, 2017.
In what is likely a first in the industry, Vizio is on the verge of agreeing to display a class-action lawsuit message through its previously sold “Smart TV” televisions as part of a legal settlement. This message is meant to alert customers who bought the TV that they will be party to the forthcoming settlement and likely will get a small amount of money.
As Ars has reported previously, the manufacturer has been under scrutiny since a 2015 revelation that it was snooping on its customers.
The tracking started in February 2014 on both new TVs and previously sold devices that didn’t originally ship with ACR software installed. The software periodically appended IP addresses to the collected data and also made it possible for more detailed personal information—including age, sex, income, marital status, household size, education level, home ownership, and home values—to be associated.
Eventually, the company agreed to pay $2.2 million to settle a complaint brought by the Federal Trade Commission.
However, this new settlement is related to an entirely separate lawsuit, one that was consolidated in federal court in Los Angeles.
In a court filing submitted last Wednesday, lawyers for both sides asked the judge to push back approval of the preliminary settlement to October 3.
“The Parties are developing a class notice program with direct notification to the class through VIZIO Smart TV displays, which requires testing to make sure any TV notice can be properly displayed and functions as intended,” they wrote. “The additional time requested will allow the parties to confirm that the notice program proposed in the motion for preliminary approval is workable and satisfies applicable legal standards.”
The atoms and bowl are exactly like this. Except the bowl is red and the atoms have a softer shell.
Lasers? Individual atoms trapped next to hot surfaces? Lots of dense text about degrees of freedom and stuff? I have found the after life, and it is a big quantum optics experiment.
Researchers have shown how to trap and cool atoms right next to a hot surface. This sounds a bit abstract. But if we ever want to make use of ultra cold atoms in sensors, this is exactly what we need to be able to do.
The basic idea behind these sorts of studies is that single atoms make highly sensitive probes for magnetic fields. They can be used to model complicated quantum systems to perform calculations for us. They can be used to help with quantum key distribution. There is almost nothing that cannot be done given a laser and some ultra cold atoms.
Keeping cool next to a hot plate
The down side is that the ultra cold atoms usually sit inside a large vacuum chamber, isolated from everything. A cloud of atoms in the middle of the vacuum chamber is easy to detect; a single atom is really difficult. However, single atoms are what we would ideally want to use in a calculating device or sensor.
To communicate with single atoms, we want them up close and personal with light delivery systems. That puts the atoms in a predictable position, and it exposes them to higher intensity light so that they respond more efficiently. It also puts an atom that might have a temperature of a few nanoKelvin in close proximity to a surface that’s at room temperature. An experience like this does not end happily for the atom.
Picture the atom as sitting in the bottom of a bowl made of laser light. The atom never sits still. Instead, it rolls back and forth on the bottom of the bowl.
The surface nearby (I think we’d all agree that ~300nm is nearby) doesn’t leave the atom alone. Surfaces, even if mounted as rigidly as possible, move and vibrate. These tiny fluctuations give the atom little shoves and kicks. As a result, the atom starts rolling further and further up the sides of the bowl. This being quantum mechanics, the atom has to take on specific rolling motions (or energy). So as the atom gets hotter, it climbs up a ladder of energetic states.
Eventually, the atom reaches the top of the bowl and flies away, only to plow into the hard stainless steel wall of the vacuum chamber. It never ends well for the atom.
Even if the sides of the bowl were continuously raised so that the atom was held in the trap, the high temperature prevents its use. Heating the atom leaves it in an unknown motional state, while we need to know its motional state to manipulate it if we’re going to use it for sensing and calculation.
Snakes and ladders with laser-powered dice
The alternative is to continuously cool the atom, which comes with its own challenges. Yet this is exactly what researchers from Austria and Germany have done.
The researchers’ high-temperature surface was an optical fiber stretched out until it was just 250nm in diameter. Cooled cesium atoms were dropped onto the fiber and held in place by light along it. That works because part of the light field leaks out of the fiber, and it holds the atoms about 300nm above the surface.
At this stage, if nothing is done, the fiber heats the atom and they are blown out of the trap in about 75 milliseconds.
To cool the atoms, we have to play with the atom and trap. The atom trap is a bowl, but the shape of the bowl depends on the internal state of the atom and an applied magnetic field. Effectively, you have two traps. The first trap corresponds to the atom in one internal state, which I’ll call the addressable state. The second trap corresponds to the atom in a second internal state, which I’ll call the hidden state.
The applied magnetic field reshapes the two traps so that their energy ladders align, except the alignment is offset by one step. Meaning the second rung of the hidden state ladder aligns with the bottom rung of the addressable state ladder.
The light in the fiber only excites our atom if it’s on the excitable state ladder. A laser flips the atom back into hidden state, causing it to climb down one rung on the ladder as it leaves. After a bit of poking to change the atom’s internal state, it returns to the addressable state ladder, but with a lower energy (see picture).
Diagram of how the atom changes energy. The laser (red arrow) drives the atom out of the right hand (addressable) trap. The atom falls back into the hidden trap at a lower energy level. The atom eventually flips back to the addressable trap (green arrow), allowing the process to repeat.
By repeatedly doing this, the atom falls down to the bottom rung of the hidden state ladder. At the bottom rung, there is no equivalent rung in the addressable state, so the atom is trapped in the lowest energy level of the hidden state. Hence, the atom is as cold as possible, which is exactly what we want.
In practice, it’s not quite there. The fiber always heats the atom. However, the researchers demonstrated that they could cool efficiently enough that it never gets warm enough to leave. Well, not quite indefinitely: the vacuum around the atom is not perfect. Every now and again, a high-velocity water molecule punts the atom out of the trap. Nevertheless, a trap time of nearly two seconds is pretty cool.
Beating the heat
The researchers haven’t yet managed to get atoms into the lowest possible state in the trap. Their cooling rate is sufficient: they suck energy out at about 20 times the rate that the nearby fiber adds it. The problem is the optimization of the experiment. When an atom is in the lowest possible state, it is not completely blind to the lasers that do the trapping and cooling. The power of these lasers is such that they occasionally kick the atom out of the ground state themselves. The result is that, on average, the atom is never quite in the ground state.
The researchers note that their setup is such that they can optimize the power of the laser. When that happens, they should have atoms that stay in the ground state for considerably longer periods of time. From there, then, the real fun can begin: quantum information processing with little arrays of atoms. I’m looking forward to it.
The quest to find the perfect movie on Netflix can sometimes be a difficult one. Better Browse aims to make that process at least a tiny bit easier by sorting Netflix’s content into additional categories.
The Chrome extension adds a “Browse all” menu to the Netflix menu bar with a ton of “hidden categories” that sort Netflix’s traditional categories into more specific genres. For instance, instead of just “Action” movies you can sort by “Action comedy” and “Action Thrillers.”
Better Browse is a Chrome extension, so, unfortunately, that means all those searches are going to have to happen on your computer rather than your television. That said, you could easily sit down for a few minutes and dig up some content to add it to your watchlist and then access all those fabulous finds on your television when you’re ready to watch.
The supposed leaked box of the OnePlus 6T that showed up last week might be the real deal after all. Remember how it teased an in-display fingerprint reader for OnePlus’ next phone? OnePlus confirmed that the 6T will indeed feature the new screen scanning tech.
In a brief statement sent to CNET, OnePlus acknowledged the new addition while saying that “By adding this feature as an addition to other display unlocking options such as Face Unlock, users will have options to unlock the display in a way that is most efficient for them.”
Curious how an in-display fingerprint reader works? Checkout this post from CES where we went hands-on with one of the first.
That introduction of an in-display fingerprint reader caused them to have to re-arrange some of the internals of the 6T, though. So if you thought this was just a re-packaging of the OnePlus 6, you might be in for somewhat of a surprise. The OnePlus 6T will be slightly thicker too (0.45mm), but without the need for a rear fingerprint reader, the phone should look incredibly clean.
The screenshot above is from the OnePlus 6T and shows how the in-display fingerprint tech will look when you have it activated. I’d also point out that the date there says October 17, which could very well be the launch day for this phone. We were already expecting it to arrive in October (possibly on T-Mobile), but my guess is that that mention was deliberate.
, while mostly unchanged, does come with a number of nice new features such as electronically adjustable Fox Racing shocks, Recaro seats and a couple of new colors. It also now comes with a handy off-road feature called Trail Control. Basically, it’s cruise control for off-roading. It lets you set a speed between 1 and 20 mph for driving off road and will maintain that speed. Not only that, but it also can adjust how much power goes to each wheel for optimal traction.
released video footage showing how it all works. One particularly useful feature of the system is that it has a mode for helping get the truck unstuck from deep sand. It’s not quite as dramatic as
