If you love LEGOs, you might have imagined building a real house from them. And with the surging popularity of 3D printers, such a dream seems well within reach. Nick Johnson, a spokesman for real estate blog Movoto, decided to find out what it would take to build a 3D-printed house.

"Given that we're due to get our own 3D printer here in the Movoto office soon, I pretty much couldn't be more excited by the possibilities the technology introduces," Johnson wrote in a company blog post. "So, with that, I thought I'd look into exactly how realistic it would be to print the components needed to build a house using one of these devices."

As it turns out, if you were to use today's 3D printing technology, you would be long dead by the time your pieces were printed. In fact, it would take 220 years, four months and 11 days for a single machine to print the 27,735 bricks required to construct a 2,500-square-foot (232 square meters), two-story house. And if you think the endeavor sounds time-costly, you should read the price tag: $332,820 in plastic alone.

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A dragonfly snatching a meal in midair is nothing short of an aerial dogfight. First, it must predict the trajectory of its prey, maneuver a course of intersection and make split-second adaptations to outwit evasive mosquitoes or fruit flies.

All this rapid-fire multitasking takes some serious neurological circuitry — the kind scientists are so interested in, they've designed a tiny dragonfly backpack to measure its brain activity.

Created by Anthony Leonardo, a neuroscientist at the Howard Hughes Medical Institute (HHMI), the backpack weighs about as much as a couple grains of salt — around 40 milligrams — and compromises just 10% of the dragonfly's body weight.

Neurological electric activity is captured by electrodes inserted into the dragonfly's brain and body, on which a small computer chip amplifies and wirelessly transmits signals to a nearby computer.

Powering the computer chip without adding too much weight to the payload proved to be a difficult task. However, in collaboration with colleagues at Duke University and Intan Technologies, Leonardo came up with an ingenious solution. You know those RFID key card systems on office or apartment buildings — the ones you swipe near small pads that emit radio waves, which in turn induce a current into the card's chip and transmit a code to unlock a door? Well, Leonardo applied similar technology. He put two long, lightweight antennae on the dragonfly backpack that pick up radio waves to power the chip.

Researchers released fruit flies inside a lab, while 18 high-speed cameras were on hand to record every second as the dragonflies took off from a perch and nabbed their prey. The backpack documented the firing of neurons, which Leonard says play a crucial roll in predators capturing their prey.

SEE ALSO: App Lets You Map Room Like A Bat

However, hunting inside a plain white lab room wasn't so appetizing for the dragonflies. Many of the insects exhausted themselves because they where more interested in escaping than hunting. To create a more natural habitat, researchers draped the walls with imagery of a spring meadow, carpeted the floor with turf and installed a small pond.

The scenic backdrop was successful and Leonardo continued his own hunt, after the questions that fascinate him most: how neurons translate a visual scene into a plan of action and how a dragonfly continuously updates that plan during its midair dogfight.

"We know a lot about their anatomy. They gather input from visual parts of the brain and send axons down to the motor neurons that move the wings," Leonardo said, according to Wired. "The dragonfly is a convenient and beautiful and elegant means to an end.

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NASA's Mars rover Curiosity, which for almost a year has been driving across the Red Planet, will be the next model to roll off LEGO's CUUSOO production line, the toy company announced on June 14.

The Denmark-based LEGO Group chose a fan-built model of the car-size rover to be the next release in its CUUSOO line of building brick toys.

"We learned that this product has niche appeal and strong demand from the space and education communities," said LEGO's Tim Courtney in a blog posted to the company's website. "The product aligns well with the LEGO Group's mission to 'inspire and develop the builders of tomorrow,' including those who will build our future in outer space." Read more…

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The traditional method of imaging, which is at least 150 years old, relies on a lens to create an image and a device for recording photons such as an array of pixels, a light-sensitive film or even a retina.

But a dramatic revolution that is currently taking the world of imaging by storm means that this could soon change.

This revolution is based on a technique called compressive sensing, which is based on the idea that many common measurements have huge redundancy. That means it’s possible to acquire the same data with just a fraction of carefully chosen measurements.

The trick, of course, is knowing which measurements to take and how to reassemble them. Various teams have been excitedly experimenting with this idea. Back in January, for example, we looked at one group who have created 3D images using a single pixel in this way.

Today, this revolution gains pace because Gang Huang and his team from Bell Labs in New Jersey say they’ve used compressive sensing to build a camera that needs no lens and uses only a single sensing pixel to take photographs. What’s more, the images from this camera are never out of focus.

The new device is simple in nature. “The architecture consists of two components, an aperture assembly and a sensor. No lens is used,” says Huang. It consists of an LCD panel that acts as an array of apertures that each allow light to pass through and a single sensor capable of detecting light three colours.

Each aperture in the LCD array is individually addressable and so can be open to allow light to pass through or closed. An important aspect of this kind of imaging is that the array of open and closed apertures must be random.

The process of creating an image is straightforward. It begins with the sensor recording the light from the scene that has passed through a random array of apertures in the LCD panel. It then records the light from a different random array and then another and so on.

Although seemingly random, each of these snapshots is correlated because they record the same scene in a different way. And this is the key that the team use to reassemble an image. The process of compressive sensing analyses the data, looking for this correlation which it then uses to recreate the image.

Clearly, the more snapshots that are taken, the better the image will be. But it is possible to create a pretty good image using just a tiny fraction of the data that a conventional image would require.

For example, the Bell Labs team took this image of books using only a quarter of the data they could have recorded.

In fact, the less detail there is in the scene, the less data is required to reconstruct it.

This revolutionary lensless camera has a number of advantages over a conventional camera. First is the tiny amount of data required to create images. Without a lens, these images suffer none of the aberrations and focusing problems associated with lenses. The scene is entirely in focus and the resolution of the image depends on the size and number of the apertures and the point-like nature of the light sensor.

By using two sensors behind the same aperture array, it is possible to create two different images of the scene at the same time. Indeed, multiple sensors produce multiple images.

What’s more, the device is simple and cheap. Huang's team built their prototype using cheap off-the-shelf components that anybody would have access to.

Best of all, the same approach works for other wavelength of light such as infrared and millimetre waves. So it ought to be possible to create relatively cheap cameras for these wavelengths, too.

The disadvantage, at least for the moment, is that it takes time to acquire the data for each image, so the camera only creates images of still scenes.

But even that is useful for surveillance since it is possible to compare consecutive images of the same scene to determine things that have changed or to work out the speed of moving objects.

That’s an impressive piece of work that is likely to have far-reaching consequences for the way we record the world around us. Expect to hear a lot more about compressive imaging — or ghost imaging as it is sometimes called — in the near future.

It’s also interesting to see Bell Labs hitting its straps again. This is an organisation with a venerable history but a tumultuous recent past. With advances like this, there is always the chance it can recapture some of its former glory.

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Astronauts tweeting from space have quietly captivated followers for a while now, but when Chris Hadfield's cover of David Bowie's "Space Oddity" went viral, the YouTube video seemed to revive people's interest in just how thrilling it is when space and Earth are bridged by simple, everyday technology.

To appeal to this new wave of fascination, the European Space Agency (ESA) and Massachusetts Institute of Technology (MIT) have created the Zero Robotics Competition, a tournament in which high school students can compete for points by controlling robotic, basketball-sized spheres that will float inside the International Space Station (ISS). Read more…

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Attention wannabe pilots: Here's your chance to experience the next best thing to flying Boeing's new 787 Dreamliner. The company created the Boeing 787 Dreamliner "Dream Pass," a 360-degree online video that lets you take an immersive virtual ride in the plane's flight deck, and tour its wings and engines.

Be sure to click the full-screen icon at the bottom of the screen for the maximum panoramic effect, where you can control your view by clicking and dragging your cursor. At the same time, you're able to select either Boeing 787 chief pilot Capt. Randy Neville's commentary (and some Boeing cheerleading) about what the pilots are doing, or you can hear the in-flight conversations between the pilots and air traffic controllers. I found both to be equally fascinating. Read more…

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