blog-5

We help you in the kitchen

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blog-3

Set your time for relax

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blog-4

Don’t worry about your home

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blog-6

Control Lighs

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Security tips for you home

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Control your home via app

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waterhunt

NASA’s VIPER lunar rover will hunt water on the Moon in 2022

NASA is looking for liquid gold on the Moon — not oil, but plain-old water. If we’re going to have a permanent presence there, we’ll need it, so learning as much as we can about it is crucial. That’s why the agency is sending a rover called VIPER to the Moon’s south pole — its first long-term surface mission since 1972.

VIPER, or the Volatiles Investigating Polar Exploration Rover, will touch down in December 2022 if all goes according to plan. Its mission: directly observe and quantify the presence of water in the permanently shadowed polar regions.

These perennially dark areas of the Moon have been collecting water ice for millions of years, since there’s no sunlight to melt or vaporize it. NASA already confirmed the presence of water ice by crashing a probe into the general area, but that’s a bit crude, isn’t it? Better to send a robot in to take some precise measurements.

VIPER will be about the size of a golf cart, and will be equipped with what amounts to prospecting gear. Its Neutron Spectrometer System (mentioned yesterday by NASA Administrator Jim Bridenstine ahead of this announcement) will let the rover detect water beneath the surface.

When it’s over a water deposit, VIPER will deploy… The Regolith and Ice Drill for Exploring New Terrain, or TRIDENT. Definitely the best acronym I’ve encountered this week. TRIDENT is a meter-long drill that will bring up samples for analysis by the rover’s two other instruments, a pair of spectrometers that will evaluate the contents of the soil.

By doing this systematically over a large area, the team hopes to create a map of water deposits below the surface that can be analyzed for larger patterns — perhaps leading to a more systematic understanding of our favorite substance’s presence on the Moon.

A visualization of Moon-based water ice under the surface being mapped by the VIPER rover

The rover is currently in development, as you can see from the pictures at the top — the right image is its “mobility testbed,” which as you might guess lets the team test out how it will get around.

VIPER is a limited-time mission; operating at the poles means there’s no sunlight to harvest with solar panels, so the rover will carry all the power it needs to last about a hundred days there. That’s longer than the U.S. has spent on the Moon’s surface in a long time — although China has for the last few years been actively deploying rovers all over the place.

Interestingly, the rover is planned for deployment via a Commercial Lunar Payload Services contract, meaning one of these companies may be building the lander that takes it from orbit to the surface. Expect to hear more as we get closer to launch.

GettyImages-feynman

Quantum computing’s ‘Hello World’ moment

Does quantum computing really exist? It’s fitting that for decades this field has been haunted by the fundamental uncertainty of whether it would, eventually, prove to be a wild goose chase. But Google has collapsed this nagging superposition with research not just demonstrating what’s called “quantum supremacy,” but more importantly showing that this also is only the very beginning of what quantum computers will eventually be capable of.

This is by all indications an important point in computing, but it is also very esoteric and technical in many ways. Consider, however, that in the 60s, the decision to build computers with electronic transistors must have seemed rather an esoteric point as well. Yet that was in a way the catalyst for the entire Information Age.

Most of us were not lucky enough to be involved with that decision or to understand why it was important at the time. We are lucky enough to be here now — but understanding takes a bit of explanation. The best place to start is perhaps with computing and physics pioneers Alan Turing and Richard Feynman.

‘Because nature isn’t classical, dammit’

The universal computing machine envisioned by Turing and others of his generation was brought to fruition during and after World War II, progressing from vacuum tubes to hand-built transistors to the densely packed chips we have today. With it evolved an idea of computing that essentially said: If it can be represented by numbers, we can simulate it.

That meant that cloud formation, object recognition, voice synthesis, 3D geometry, complex mathematics — all that and more could, with enough computing power, be accomplished on the standard processor-RAM-storage machines that had become the standard.

But there were exceptions. And although some were obscure things like mathematical paradoxes, it became clear as the field of quantum physics evolved that it may be one of them. It was Feynman who proposed in the early 80s that if you want to simulate a quantum system, you’ll need a quantum system to do it with.

“I’m not happy with all the analyses that go with just the classical theory, because nature isn’t classical, dammit, and if you want to make a simulation of nature, you’d better make it quantum mechanical,” he concluded, in his inimitable way. Classical computers, as he deemed what everyone else just called computers, were insufficient to the task.

Richard Feynman made the right call, it turns out.

The problem? There was no such thing as a quantum computer, and no one had the slightest idea how to build one. But the gauntlet had been thrown, and it was like catnip to theorists and computer scientists, who since then have vied over the idea.

Could it be that with enough ordinary computing power, power on a scale Feynman could hardly imagine — data centers with yottabytes of storage and exaflops of processing — we can in fact simulate nature down to its smallest, spookiest levels?

Or could it be that with some types of problems you hit a wall, and that you can put every computer on Earth to a task and the progress bar will only tick forward a percentage point in a million years, if that?

And, if that’s the case, is it even possible to create a working computer that can solve that problem in a reasonable amount of time?

In order to prove Feynman correct, you would have to answer all of these questions. You’d have to show that there exists a problem that is not merely difficult for ordinary computers, but that is effectively impossible for them to solve even at incredible levels of power. And you would have to not just theorize but create a new computer that not just can but does solve that same problem.

By doing so you would not just prove a theory, you would open up an entirely new class of problem-solving, of theories that can be tested. It would be a moment when an entirely new field of computing first successfully printed “hello world” and was opened up for everyone in the world to use. And that is what the researchers at Google and NASA claim to have accomplished.

In which we skip over how it all actually works

One of the quantum computers in question. I talked with that fellow in the shorts about microwave amps and attenuators for a while.

Much has already been written on how quantum computing differs from traditional computing, and I’ll be publishing another story soon detailing Google’s approach. But some basics bear mentioning here.

Classical computers are built around transistors that, by holding or vacating a charge, signify either a 1 or a 0. By linking these transistors together into more complex formations they can represent data, or transform and combine it through logic gates like AND and NOR. With a complex language specific to digital computers that has evolved for decades, we can make them do all kinds of interesting things.

Quantum computers are actually quite similar in that they have a base unit that they perform logic on to perform various tasks. The difference is that the unit is more complex: a qubit, which represents a much more complex mathematical space than simply 0 or 1. Instead you may think of their state may be thought of as a location on a sphere, a point in 3D space. The logic is also more complicated, but still relatively basic (and helpfully still called gates): That point can be adjusted, flipped, and so on. Yet the qubit when observed is also digital, providing what amounts to either a 0 or 1 value.

By virtue of representing a value in a richer mathematical space, these qubits and manipulations thereof can perform new and interesting tasks, including some which, as Google shows, we had no ability to do before.

A quantum of contrivance

In order to accomplish the tripartite task summarized above, first the team had to find a task that classical computers found difficult but that should be relatively easy for a quantum computer to do. The problem they settled on is in a way laughably contrived: Being a quantum computer.

In a way it makes you want to just stop reading, right? Of course a quantum computer is going to be better at being itself than an ordinary computer will be. But it’s not actually that simple.

Think of a cool old piece of electronics — an Atari 800. Sure, it’s very good at being itself and running its programs and so on. But any modern computer can simulate an Atari 800 so well that it could run those programs in orders of magnitude less time. For that matter, a modern computer can be simulated by a supercomputer in much the same way.

Furthermore, there are already ways of simulating quantum computers — they were developed in tandem with real quantum hardware so performance could be compared to theory. These simulators and the hardware they simulate differ widely, and have been greatly improved in recent years as quantum computing became more than a hobby for major companies and research institutions.

This shows the “lattice” of qubits as they were connected during the experiment (colored by the amount of error they contributed, which you don’t need to know about.)

To be specific, the problem was simulating the output of a random sequence of gates and qubits in a quantum computer. Briefly stated, when a circuit of qubits does something, the result is, like other computers, a sequence of 0s and 1s. If it isn’t calculating something in particular, those numbers will be random — but crucially, they are “random” in a very specific, predictable way.

Think of a pachinko ball falling through its gauntlet of pins, holes and ramps. The path it takes is random in a way, but if you drop 10,000 balls from the exact same position into the exact same maze, there will be patterns in where they come out at the bottom — a spread of probabilities, perhaps more at the center and less at the edges. If you were to simulate that pachinko machine on a computer, you could test whether your simulation is accurate by comparing the output of 10,000 virtual drops with 10,000 real ones.

It’s the same with simulating a quantum computer, though of course rather more complex. Ultimately however the computer is doing the same thing: simulating a physical process and predicting the results. And like the pachinko simulator, its accuracy can be tested by running the real thing and comparing those results.

But just as it is easier to simulate a simple pachinko machine than a complex one, it’s easier to simulate a handful of qubits than a lot of them. After all, qubits are already complex. And when you get into questions of interference, slight errors and which direction they’d go, etc. — there are, in fact, so many factors that Feynman decided at some point you wouldn’t be able to account for them all. And at that point you would have entered the realm where only a quantum computer can do so — the realm of “quantum supremacy.”

Exponential please, and make it a double

After 1,400 words, there’s the phrase everyone else put right in the headline. Why? Because quantum supremacy may sound grand, but it’s only a small part of what was accomplished, and in fact this result in particular may not last forever as an example of having reached those lofty heights. But to continue.

Google’s setup, then, was simple. Set up randomly created circuits of qubits, both in its quantum computer and in the simulator. Start simple with a few qubits doing a handful of operational cycles and compare the time it takes to produce results.

Bear in mind that the simulator is not running on a laptop next to the fridge-sized quantum computer, but on Summit — a supercomputer at Oak Ridge National Lab currently rated as the most powerful single processing system in the world, and not by a little. It has 2.4 million processing cores, a little under 3 petabytes of memory, and hits about 150 petaflops.

At these early stages, the simulator and the quantum computer happily agreed — the numbers they spat out, the probability spreads, were the same, over and over.

But as more qubits and more complexity got added to the system, the time the simulator took to produce its prediction increased. That’s to be expected, just like a bigger pachinko machine. At first the times for actually executing the calculation and simulating it may have been comparable — a matter of seconds or minutes. But those numbers soon grew hour by hour as they worked their way up to 54 qubits.

When it got to the point where it took the simulator five hours to verify the quantum computer’s result, Google changed its tack. Because more qubits isn’t the only way quantum computing gets more complex (and besides, they couldn’t add any more to their current hardware). Instead, they started performing more rounds of operations with a given circuit, which adds all kinds of complexity to the simulation for a lot of reasons that I couldn’t possibly explain.

For the quantum computer, doing another round of calculations takes a fraction of a second, and even multiplied by thousands of times to get the required number of runs to produce usable probability numbers, it only ended up taking the machine several extra seconds.

You know it’s real because there’s a chart. The dotted line (added by me) is the approximate path the team took, first adding qubits (x-axis) and then complexity (y-axis).

For the simulator, verifying these results took a week — a week, on the most powerful computer in the world.

At that point the team had to stop doing the actual simulator testing, since it was so time-consuming and expensive. Yet even so, no one really claimed that they had achieved “quantum supremacy.” After all, it may have taken the biggest classical computer ever created thousands of times longer, but it was still getting done.

So they cranked the dial up another couple notches. 54 qubits, doing 25 cycles, took Google’s Sycamore system 200 seconds. Extrapolating from its earlier results, the team estimated that it would take Summit 10,000 years.

What happened is what the team called double exponential increase. It turns out that adding qubits and cycles to a quantum computer adds a few microseconds or seconds every time — a linear increase. But every qubit you add to a simulated system makes that simulation exponentially more costly to run, and it’s the same story with cycles.

Imagine if you had to do whatever number of push-ups I did, squared, then squared again. If I did 1, you would do 1. If I did 2, you’d do 16. So far no problem. But by the time I get to 10, I’d be waiting for weeks while you finish your 10,000 push-ups. It’s not exactly analogous to Sycamore and Summit, since adding qubits and cycles had different and varying exponential difficulty increases, but you get the idea. At some point you can have to call it. And Google called it when the most powerful computer in the world would still be working on something when in all likelihood this planet will be a smoking ruin.

It’s worth mentioning here that this result does in a way depend on the current state of supercomputers and simulation techniques, which could very well improve. In fact IBM published a paper just before Google’s announcement suggesting that theoretically it could reduce the time necessary for the task described significantly. But it seems unlikely that they’re going to improve by multiple orders of magnitude and threaten quantum supremacy again. After all, if you add a few more qubits or cycles, it gets multiple orders of magnitude harder again. Even so, advances on the classical front are both welcome and necessary for further quantum development.

‘Sputnik didn’t do much, either’

So the quantum computer beat the classical one soundly on the most contrived, lopsided task imaginable, like pitting an apple versus an orange in a “best citrus” competition. So what?

Well, as founder of Google’s Quantum AI lab Hartmut Neven pointed out, “Sputnik didn’t do much either. It just circled the Earth and beeped.” And yet we always talk about an industry having its “Sputnik moment” — because that was when something went from theory to reality, and began the long march from reality to banality.

The ritual passing of the quantum computing core.

That seemed to be the attitude of the others on the team I talked with at Google’s quantum computing ground zero near Santa Barbara. Quantum superiority is nice, they said, but it’s what they learned in the process that mattered, by confirming that what they were doing wasn’t pointless.

Basically it’s possible that a result like theirs could be achieved whether or not quantum computing really has a future. Pointing to one of the dozens of nearly incomprehensible graphs and diagrams I was treated to that day, hardware lead and longtime quantum theorist John Martines explained one crucial result: The quantum computer wasn’t doing anything weird and unexpected.

This is very important when doing something completely new. It was entirely possible that in the process of connecting dozens of qubits and forcing them to dance to the tune of the control systems, flipping, entangling, disengaging, and so on — well, something might happen.

Maybe it would turn out that systems with more than 14 entangled qubits in the circuit produce a large amount of interference that breaks the operation. Maybe some unknown force would cause sequential qubit photons to affect one another. Maybe sequential gates of certain types would cause the qubit to decohere and break the circuit. It’s these unknown unknowns that have caused so much doubt over whether, as asked at the beginning, quantum computing really exists as anything more than a parlor trick.

Imagine if they discovered that in digital computers, if you linked too many transistors together, they all spontaneously lost their charge and went to 0. That would put a huge limitation on what a transistor-based digital computer was capable of doing. Until now, no one knew if such a limitation existed for quantum computers.

“There’s no new physics out there that will cause this to fail. That’s a big takeaway,” said Martines. “We see the same errors whether we have a simple circuit or complex one, meaning the errors are not dependent on computational complexity or entanglement — which means the complex quantum computing going on doesn’t have fragility to it because you’re doing a complex computation.”

They operated a quantum computer at complexities higher than ever before, and nothing weird happens. And based on their observations and tests, they found that there’s no reason to believe they can’t take this same scheme up to, say, a thousand qubits and even greater complexity.

Hello world

That is the true accomplishment of the work the research team did. They found out, in the process of achieving the rather overhyped milestone of quantum superiority, that quantum computers are something that can continue to get better and to achieve more than simply an interesting experimental results.

This was by no means a given — like everything else in the world, quantum or classical, it’s all theoretical until you test it.

It means that sometime soonish, though no one can really say when, quantum computers will be something people will use to accomplish real tasks. From here on out, it’s a matter of getting better, not proving the possibility; of writing code, not theorizing whether code can be executed.

It’s going from Feynman’s proposal that a quantum computer will be needed to using a quantum computer for whatever you need it for. It’s the “hello world” moment for quantum computing.

Feynman, by the way, would probably not be surprised. He knew he was right.

Google’s paper describing their work was published in the journal Nature. You can read it here.

lidar_show

Sense Photonics brings its fancy new flash lidar to market

There’s no shortage of lidar solutions available for autonomous vehicles, drones and robots — theoretically, anyway. But getting a lidar unit from theory to mass production might be harder than coming up with the theory in the first place. Sense Photonics appears to have made it past that part of the journey, and is now offering its advanced flash lidar for pre-order.

Lidar comes in a variety of form factors, but the spinning type we’ve seen so much of is on its way out, and more compact, reliable planar types are on the way in; Luminar is making moves to get ahead, but Sense Photonics isn’t sitting still — and anyway, the two companies have different strengths.

While Luminar and some other companies aim to create a forward-facing lidar that can detect shapes hundreds of feet ahead in a relatively narrow field of view, Sense is going after the short-range, wide-angle side of things. And because they sync up with regular cameras, it’s easy as pie to map depth onto the RGB image:

Sense Photonics makes it easy to match traditional camera views with depth data

These are lidars that you’d want mounted on the rear or sides of the vehicles, able to cover a wide slice of the surroundings and get accurate detection of things like animals, kids and bikes quickly and accurately. But I went through all this when they came out of stealth.

The news today is that these units have gone from prototype to production design. The devices have been ruggedized so they can be attached outside of enclosures even in dusty or rainy environments. And performance has been improved, bumping the maximum range in some cases out to more than 40 meters, well over what was promised before.

The base price of $2,900 covers a unit with an 80×30 degree field of view, but others cover wider areas, up to 95×75 degrees — a large amount by lidar standards, and in higher fidelity than other flash lidars out there. You do give up some other properties in return for the wide view, though. The proprietary tech created by the company lets the lidar’s detector be located elsewhere than the laser emitter, too, which makes designing around the things easier (if not exactly easy).

Obviously if people are meant to order these online from the company these are not going to be appearing in next year’s autonomous vehicles. No, it’s more for bulk purchases by companies doing serious testing in industry settings.

Whether the Sense Photonics kit or some other lucky lidar company’s ends up on the robo-fleets of tomorrow is up in the air, but it does help for your product to actually exist. You can find out more about the company’s lidar platform here.

Cowboy-5

A bike lover’s take on the Cowboy e-bike

Electric-bike maker Cowboy recently let me spend a couple of weeks with one of their e-bikes. It’s a well-designed e-bike that makes biking effortless, even if you’re going uphill.

Cowboy is a Brussels-based startup. The company raised a million seed round a couple of years ago and an .1 million (€10 million) Series A round last year.

The company designs e-bikes from scratch. Components feel more integrated than in a normal e-bike. And it also opens up some possibilities when it comes to connectivity and smart features.

Cowboy sells its bikes directly to consumers on its online store. It is currently available in Belgium, France, Germany, the Netherlands and Austria for €2,000 ($2,220).

I rode 70 kilometers (43 miles) in the streets of Paris to try it out. For context, riding a bike in Paris is nothing new for me. I primarily use my non-electric bike to go from point A to point B — bikes are commuting devices for me. And given that Cowboy is primarily designed for densely populated cities, I thought I’d give it a try.

From the outside, the Cowboy e-bike is a sleek bike. It features a seamless triangle-shaped aluminum frame, integrated lights and a low-key Cowboy logo near the saddle. The handlebar is perfectly straight like on a mountain bike. The only sign that this is an e-bike is that the frame is much larger below the saddle.

The e-bike is relatively light at 16 kg (35 lbs). Most of the weight is at the back of the Cowboy e-bike because of the battery. But an investor in the startup told me that it wasn’t a problem and that he was even able to attach a baby seat at the back.

There are two things you’re going to notice quite quickly: there are no gears and there’s a rubber and fiberglass belt. Cowboy has opted for an automatic transmission — motor assistance kicks in automatically when you need it the most, such as when you start pedaling, accelerate or go uphill.

If you usually ride on a normal bike, this feels weird at first. I constantly shift from one gear to another. With the Cowboy e-bike, you have to trust the bike and forget about gears.

The electric motor kicks in a second after you start pedaling. It means that you are much faster than people using regular bikes. And you can reach a speed of 30 to 35 kmph in no time (18 to 22 mph). Yes, this bike is fast.

Fortunately, the brakes work surprisingly well. You have to be careful with them. If you’re braking too hard, you’ll skid, especially if it’s raining.

I was able to ride from one end of Paris to another without breaking a sweat. Sure, the Cowboy e-bike is fast, but I only saved a few minutes compared to my non-electric bike. You still spend a lot of time waiting at big intersections.

In fact, riding the Cowboy e-bike felt more like riding a moped-style scooter. You start your engine at a green light, ride as quickly as possible, brake aggressively at a red light and spend more time waiting at intersections. I believe an e-bike makes more sense in larger cities with huge hills. Paris is much, much smaller than London or Berlin, after all.

You may have noticed that the Cowboy e-bike doesn’t have fenders. Cowboy will start selling custom-designed fenders for €89 in a few weeks ($100).

Another thing worth noting is that you have to be relatively tall to use the Cowboy e-bike. I’m 1.75 m tall (5’ 8”) and I lowered the saddle as much as possible. If you’re just a tiny bit smaller than me, chances are it’s going to be too high for you. Similarly, naming your brand “Cowboy” doesn’t make your bike particularly attractive for women.

When it comes to connectivity, the Cowboy e-bike isn’t just an electric bike — it’s also a smart bike. It has built-in GPS tracking and an integrated SIM card.

After pairing the bike with your phone using Bluetooth, you can control it from a mobile app. In particular, you can lock and unlock the bike, turn on and off the lights and check the battery. It would have been nice to put a light sensor on the bike itself as you may forget to turn on the lights at night. You also can get a rough idea of the current battery level without the mobile app — there are five LEDs on the frame of the device.

Thanks to GPS capabilities and the integrated SIM card, you can locate your bike using a feature called “Find my Bike.” The company also sells insurance packages for €8 to €10 per month with theft insurance and optionally damage insurance.

I recharged the battery once during my testing. According to the company, you can get up to 70 km on a single charge (43 miles). I got less than that, but I also tried the off-road mode, which consumes more battery. Unless you’re going on a long bike trip, range isn’t an issue for city rides.

When it’s time to recharge the battery, you can detach the battery with a key and bring it back home. This is a great feature for people living in apartments, as you can leave your bike at its normal parking spot and plug in the battery at home. The battery was full after three to four hours.

Cowboy battery charger; tomato for scale

Overall, the Cowboy e-bike is the perfect commuting bike for people living in large cities. It’s a smooth and well-designed experience. If you’re looking for an e-bike, you should definitely consider the Cowboy e-bike as one of your options. I recommend you book a test ride before buying one though.

If you’re happy with a normal bike like me, the Cowboy e-bike is 100% an e-bike. Don’t expect to get the same experience on a Cowboy e-bike. It’s a completely different thing. But I’m glad e-bikes exist, because they are going to convince more people to ditch their cars and moped-style scooters.