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#431958 The Next Generation of Cameras Might See ...

You might be really pleased with the camera technology in your latest smartphone, which can recognize your face and take slow-mo video in ultra-high definition. But these technological feats are just the start of a larger revolution that is underway.

The latest camera research is shifting away from increasing the number of mega-pixels towards fusing camera data with computational processing. By that, we don’t mean the Photoshop style of processing where effects and filters are added to a picture, but rather a radical new approach where the incoming data may not actually look like at an image at all. It only becomes an image after a series of computational steps that often involve complex mathematics and modeling how light travels through the scene or the camera.

This additional layer of computational processing magically frees us from the chains of conventional imaging techniques. One day we may not even need cameras in the conventional sense any more. Instead we will use light detectors that only a few years ago we would never have considered any use for imaging. And they will be able to do incredible things, like see through fog, inside the human body and even behind walls.

Single Pixel Cameras
One extreme example is the single pixel camera, which relies on a beautifully simple principle. Typical cameras use lots of pixels (tiny sensor elements) to capture a scene that is likely illuminated by a single light source. But you can also do things the other way around, capturing information from many light sources with a single pixel.

To do this you need a controlled light source, for example a simple data projector that illuminates the scene one spot at a time or with a series of different patterns. For each illumination spot or pattern, you then measure the amount of light reflected and add everything together to create the final image.

Clearly the disadvantage of taking a photo in this is way is that you have to send out lots of illumination spots or patterns in order to produce one image (which would take just one snapshot with a regular camera). But this form of imaging would allow you to create otherwise impossible cameras, for example that work at wavelengths of light beyond the visible spectrum, where good detectors cannot be made into cameras.

These cameras could be used to take photos through fog or thick falling snow. Or they could mimic the eyes of some animals and automatically increase an image’s resolution (the amount of detail it captures) depending on what’s in the scene.

It is even possible to capture images from light particles that have never even interacted with the object we want to photograph. This would take advantage of the idea of “quantum entanglement,” that two particles can be connected in a way that means whatever happens to one happens to the other, even if they are a long distance apart. This has intriguing possibilities for looking at objects whose properties might change when lit up, such as the eye. For example, does a retina look the same when in darkness as in light?

Multi-Sensor Imaging
Single-pixel imaging is just one of the simplest innovations in upcoming camera technology and relies, on the face of it, on the traditional concept of what forms a picture. But we are currently witnessing a surge of interest for systems that use lots of information but traditional techniques only collect a small part of it.

This is where we could use multi-sensor approaches that involve many different detectors pointed at the same scene. The Hubble telescope was a pioneering example of this, producing pictures made from combinations of many different images taken at different wavelengths. But now you can buy commercial versions of this kind of technology, such as the Lytro camera that collects information about light intensity and direction on the same sensor, to produce images that can be refocused after the image has been taken.

The next generation camera will probably look something like the Light L16 camera, which features ground-breaking technology based on more than ten different sensors. Their data are combined using a computer to provide a 50 MB, re-focusable and re-zoomable, professional-quality image. The camera itself looks like a very exciting Picasso interpretation of a crazy cell-phone camera.

Yet these are just the first steps towards a new generation of cameras that will change the way in which we think of and take images. Researchers are also working hard on the problem of seeing through fog, seeing behind walls, and even imaging deep inside the human body and brain.

All of these techniques rely on combining images with models that explain how light travels through through or around different substances.

Another interesting approach that is gaining ground relies on artificial intelligence to “learn” to recognize objects from the data. These techniques are inspired by learning processes in the human brain and are likely to play a major role in future imaging systems.

Single photon and quantum imaging technologies are also maturing to the point that they can take pictures with incredibly low light levels and videos with incredibly fast speeds reaching a trillion frames per second. This is enough to even capture images of light itself traveling across as scene.

Some of these applications might require a little time to fully develop, but we now know that the underlying physics should allow us to solve these and other problems through a clever combination of new technology and computational ingenuity.

This article was originally published on The Conversation. Read the original article.

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#431939 This Awesome Robot Is the Size of a ...

They say size isn’t everything, but when it comes to delta robots it seems like it’s pretty important.

The speed and precision of these machines sees them employed in delicate pick-and-place tasks in all kinds of factories, as well as to control 3D printer heads. But Harvard researchers have found that scaling them down to millimeter scale makes them even faster and more precise, opening up applications in everything from microsurgery to manipulating tiny objects like circuit board components or even living cells.

Unlike the industrial robots you’re probably more familiar with, delta robots consist of three individually controlled arms supporting a platform. Different combinations of movements can move the platform in three directions, and a variety of tools can be attached to this platform.



The benefit of this design is that unlike a typical robotic arm, all the motors are housed at the base rather than at the joints, which reduces their mechanical complexity, but also—importantly—the weight of the arms. That means they can move and accelerate faster and with greater precision.

It’s been known for a while that the physics of these robots means the smaller you can make them, the more pronounced these advantages become, but scientists had struggled to build them at scales below tens of centimeters.

In a recent paper in the journal Science Robotics, the researchers describe how they used an origami-inspired micro-fabrication approach that relies on folding flat sheets of composite materials to create a robot measuring just 15 millimeters by 15 millimeters by 20 millimeters.

The robot dubbed “milliDelta” features joints that rely on a flexible polymer core to bend—a simplified version of the more complicated joints found in large-scale delta robots. The machine was powered by three piezoelectric actuators, which flex when a voltage is applied, and could perform movements at frequencies 15 to 20 times higher than current delta robots, with precisions down to roughly 5 micrometers.

One potential use for the device is to cancel out surgeons’ hand tremors as they carry out delicate microsurgery procedures, such as operations on the eye’s retina. The researchers actually investigated this application in their paper. They got volunteers to hold a toothpick and measured the movement of the tip to map natural hand tremors. They fed this data to the milliDelta, which was able to match the movements and therefore cancel them out.

In an email to Singularity Hub, the researchers said that adding the robot to the end of a surgical tool could make it possible to stabilize needles or scalpels, though this would require some design optimization. For a start, the base would have to be redesigned to fit on a surgical tool, and sensors would have to be added to the robot to allow it to measure tremors in real time.

Another promising application for the device would be placing components on circuit boards at very high speeds, which could prove valuable in electronics manufacturing. The researchers even think the device’s precision means it could be used for manipulating living cells in research and clinical laboratories.

The researchers even said it would be feasible to integrate the devices onto microrobots to give them similarly impressive manipulation capabilities, though that would require considerable work to overcome control and sensing challenges.

Image Credit: Wyss institute / Harvard Continue reading

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#431553 This Week’s Awesome Stories From ...

ROBOTS
Boston Dynamics’ Atlas Robot Does Backflips Now and It’s Full-Tilt InsaneMatt Simon | Wired “To be clear: Humanoids aren’t supposed to be able to do this. It’s extremely difficult to make a bipedal robot that can move effectively, much less kick off a tumbling routine.”

TRANSPORTATION
This Is the Tesla Semi TruckZac Estrada | The Verge“What Tesla has done today is shown that it wants to invigorate a segment, rather than just make something to comply with more stringent emissions regulations… And in the process, it’s trying to do for heavy-duty commercial vehicles what it did for luxury cars—plough forward in its own lane.”
PRIVACY AND SECURITY
Should Facebook Notify Readers When They’ve Been Fed Disinformation?Austin Carr | Fast Company “It would be, Reed suggested, the social network equivalent of a newspaper correction—only one that, with the tech companies’ expansive data, could actually reach its intended audience, like, say, the 250,000-plus Facebook users who shared the debunked YourNewsWire.com story.”
BRAIN HEALTH
Brain Implant Boosts Memory for First Time EverKristin Houser | NBC News “Once implanted in the volunteers, Song’s device could collect data on their brain activity during tests designed to stimulate either short-term memory or working memory. The researchers then determined the pattern associated with optimal memory performance and used the device’s electrodes to stimulate the brain following that pattern during later tests.”
COMPUTING
Yale Professors Race Google and IBM to the First Quantum ComputerCade Metz | New York Times “Though Quantum Circuits is using the same quantum method as its bigger competitors, Mr. Schoelkopf argued that his company has an edge because it is tackling the problem differently. Rather than building one large quantum machine, it is constructing a series of tiny machines that can be networked together. He said this will make it easier to correct errors in quantum calculations—one of the main difficulties in building one of these complex machines.”
Image Credit: Tesla Motors Continue reading

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#431368 This Week’s Awesome Stories From ...

INTERNET OF THINGSAmazon Key Is a New Service That Lets Couriers Unlock Your Front DoorBen Popper | The Verge“When a courier arrives with a package for in-home delivery, they scan the barcode, sending a request to Amazon’s cloud. If everything checks out, the cloud grants permission by sending a message back to the camera, which starts recording. The courier then gets a prompt on their app, swipes the screen, and voilà, your door unlocks.”
ROBOTICSWatch Yamaha’s Humanoid Robot Ride a Motorcycle Around a RacetrackPhilip E. Ross | IEEE Spectrum“What’s striking is that the bike is unmodified: the robot is a hunched-over form on top. It senses the environment, calculates what to do, keeps the bike stable, manages acceleration and deceleration—all while factoring in road conditions, air resistance, and engine braking.”
ARTIFICIAL INTELLIGENCETech Giants Are Paying Huge Salaries for Scarce A.I. TalentCade Metz | The New York Times“Typical A.I. specialists, including both Ph.D.s fresh out of school and people with less education and just a few years of experience, can be paid from $300,000 to $500,000 a year or more in salary and company stock, according to nine people who work for major tech companies or have entertained job offers from them. All of them requested anonymity because they did not want to damage their professional prospects.”
HEALTH This Doctor Diagnosed His Own Cancer With an iPhone UltrasoundAntonio Regalado | MIT Technology Review“The device he used, called the Butterfly IQ, is the first solid-state ultrasound machine to reach the market in the U.S. Ultrasound works by shooting sound into the body and capturing the echoes. Usually, the sound waves are generated by a vibrating crystal. But Butterfly’s machine instead uses 9,000 tiny drums etched onto a semiconductor chip.”
ENTREPRENEURSHIPWeWork: A $20 Billion Startup Fueled by Silicon Valley Pixie DustEliot Brown | Wall Street Journal“WeWork’s strategy carries the costs and risks associated with traditional real estate. Its client list is heavily weighted toward startups that may or may not be around for long. WeWork is on the hook for long-term leases, and it doesn’t own its own buildings. Vacancy rates have risen recently, and the company is increasing incentives to draw tenants… The model has proved popular, with 150,000 individuals renting space in more than 170 locations globally.”
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#430955 This Inspiring Teenager Wants to Save ...

It’s not every day you meet a high school student who’s been building functional robots since age 10. Then again, Mihir Garimella is definitely not your average teenager.
When I sat down to interview him recently at Singularity University’s Global Summit, that much was clear.
Mihir’s curiosity for robotics began at age two when his parents brought home a pet dog—well, a robotic dog. A few years passed with this robotic companion by his side, and Mihir became fascinated with how software and hardware could bring inanimate objects to “life.”
When he was 10, Mihir built a robotic violin tuner called Robo-Mozart to help him address a teacher’s complaints about his always-out-of-tune violin. The robot analyzes the sound of the violin, determines which strings are out of tune, and then uses motors to turn the tuning pegs.
Robo-Mozart and other earlier projects helped Mihir realize he could use robotics to solve real problems. Fast-forward to age 14 and Flybot, a tiny, low-cost emergency response drone that won Mihir top honors in his age category at the 2015 Google Science Fair.

The small drone is propelled by four rotors and is designed to mimic how fruit flies can speedily see and react to surrounding threats. It’s a design idea that hit Mihir when he and his family returned home after a long vacation to discover they had left bananas on their kitchen counter. The house was filled with fruit flies.
After many failed attempts to swat the flies, Mihir started wondering how these tiny creatures with small brains and horrible vision were such masterful escape artists. He began digging through research papers on fruit flies and came to an interesting conclusion.
Since fruit flies can’t see a lot of detail, they compensate by processing visual information very fast—ten times faster than people do.
“That’s what enables them to escape so effectively,” says Mihir.
Escaping a threat for a fruit fly could mean quickly avoiding a fatal swat from a human hand. Applied to a search-and-response drone, the scenario shifts—picture a drone instantaneously detecting and avoiding a falling ceiling while searching for survivors inside a collapsing building.

Now, at 17, Mihir is still pushing Flybot forward. He’s developing software to enable the drone to operate autonomously and hopes it will be able to navigate environments such as a burning building, or a structure that’s been hit by an earthquake. The drone is also equipped with intelligent sensors to collect spatial data it will use to maneuver around obstacles and detect things like a trapped person or the location of a gas leak.
For everyone concerned about robots eating jobs, Flybot is a perfect example of how technology can aid existing jobs.
Flybot could substitute for a first responder entering a dangerous situation or help a firefighter make a quicker rescue by showing where victims are trapped. With its small and fast design, the drone could also presumably carry out an initial search-and-rescue sweep in just a few minutes.
Mihir is committed to commercializing the product and keeping it within a $250–$500 price range, which is a fraction of the cost of many current emergency response drones. He hopes the low cost will allow the technology to be used in developing countries.
Next month, Mihir starts his freshman year at Stanford, where he plans to keep up his research and create a company to continue work on the drone.
When I asked Mihir what fuels him, he said, “Curiosity is a great skill for inventors. It lets you find inspiration in a lot of places that you may not look. If I had started by trying to build an escape algorithm for these drones, I wouldn’t know where to start. But looking at fruit flies and getting inspired by them, it gave me a really good place to look for inspiration.”
It’s a bit mind boggling how much Mihir has accomplished by age 17, but I suspect he’s just getting started.
Image Credit: Google Science Fair via YouTube Continue reading

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