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Wearable medical technology is designed to be small and lightweight to minimize additional burden on medical Airmen and the warfighter, whether they are on a remote battlefield or aboard an aircraft.

“Wearables provide greater accessibility,” said Dr. David Burch, a research biomedical engineer and the medical technology solutions team lead for the En Route Care Medical Technology Solutions Research Group, 711th HPW. “An aircraft has a very tight space and weight limit to maintain performance, and battlefield medics need to carry everything they use. Wearables provide accessibility to the human in a way that is better form, fit, and function.”

One wearable device that achieves that accessibility is a tissue oxygenation sensor, developed jointly with a private company. This small, soft, injectable sensor lets medics determine if a patient is able to be medically evacuated by assessing how well their blood transports oxygen to tissue.

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Samsung proudly announced today that its “unbreakable smartphone panel” has been certified by Underwriters Laboratories (UL). This means this ultra durable display is much closer to very profitable things like military and automotive contracts. But let’s be serious. Somebody’s gonna find a way to break this thing, and I hope it’s me.

The new display owes its anti-destructive tendencies to a couple of innovations. Samsung says that the OLED panel has “an unbreakable substrate.” (A substrate is basically the coating that holds the display’s organic material, cathodes, and diodes together.) Additionally, the Samsung display uses a flexible new type of plastic that won’t crack like glass. So you can supposedly drop it, smash it, and bend it without breaking the display.

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Silicon computer chips have been on a roll for half a century, getting ever more powerful. But the pace of innovation is slowing. Today the U.S. military’s Defense Advanced Research Projects Agency (DARPA) announced dozens of new grants totaling $75 million in a program that aims to reinvigorate the chip industry with basic research into new designs and materials, such as carbon nanotubes. Over the next few years, the DARPA program, which supports both academic and industry scientists, will grow to $300 million per year up to a total of $1.5 billion over 5 years.

“It’s a critical time to do this,” says Erica Fuchs, a computer science policy expert at Carnegie Mellon University in Pittsburgh, Pennsylvania.

In 1965, Intel co-founder Gordon Moore made the observation that would become his eponymous “law”: The number of transistors on chips was doubling every 2 years, a time frame later cut to every 18 months. But the gains from miniaturizing the chips are dwindling. Today, chip speeds are stuck in place, and each new generation of chips brings only a 30% improvement in energy efficiency, says Max Shulaker, an electrical engineer at the Massachusetts Institute of Technology in Cambridge. Fabricators are approaching physical limits of silicon, says Gregory Wright, a wireless communications expert at Nokia Bell Labs in Holmdel, New Jersey. Electrons are confined to patches of silicon just 100 atoms wide, he says, forcing complex designs that prevent electrons from leaking out and causing errors. “We’re running out of room,” he says.

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Tomorrow it’s commercial tourism, space energy, space data centers, in-space manufacturing and resource exploration & utilization. Companies all over the world are creating incredible future technologies that will one day operate in deep space. But one question largely goes unanswered: how will they get there? We will take them.

Chemical and ion electrical propulsion have their limitations. We’re building breakthrough transportation technology to propel the next generation of space endeavors more efficiently, safely, and inexpensively than ever before.

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Harking back to Soviet big science, a 10-point plan calls for new organizations and focus areas, from job training to a giant new R&D campus.

The Russian Ministry of Defense is pursuing artificial intelligence with an urgency that has only grown since Vladimir Putin’s “rule the world” speech in September. But after several years of watching American and Chinese researchers accumulate breakthroughs and funding, while Russia continues to lack a relevant high-tech culture, Ministry leaders have decided that if they can’t outspend their global competitors, perhaps they can out-organize them.

So in March, the MOD — along with the Ministry of Education and Science of the Russian Federation, or MES ; and the Russian Academy of Sciences — gathered domestic and international developers and users at a conference intended to take stock of the world’s AI prowess, and develop plans to focus Russia’s academic, scientific, and commercial communities to compete.

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