• Thanks for stopping by. Logging in to a registered account will remove all generic ads. Please reach out with any questions or concerns.

Recent Warfare Technologies

Jim Seggie said:
I am not a gunner however I can see this piece of kit in the maintenance bay rather than on the gun line. Too complicated and too many moving parts. Plus what is the accuracy like? I recall once we bedded our 81s in we didn't like to move them until we had to leave.
That transformer rotating round and round under its own power.....radical yes....
I also thought that the dinky wheels on the rear of the assy might not do too well in some field conditions.  But you're right, lots of shit to break and cause headaches.  As for the Riverdance gun drill, I laugh everytime I watch it.  ;D
 
http://defensetech.org/2012/07/25/boeing-builds-touch-screen-sand-table-replacement/

Boeing Builds Touch Screen Sand Table Replacement

The Army can’t get enough touch screens. Walk through the Network Integration Evaluations at White Sands Missile Range, N.M. They populate the headquarters posts and tactical operations center throughout the desert. The day of the traditional sand table might be coming to a close.

One of the latest models is Boeing’s Virtual Mission Board which the Army is using to train. Dave Irwin, Boeing’s director for Ground Forces Training, said he could see it being used in combat as well.

The Virtual Mission Board is less a board as much as it’s a software program that soldiers or other services could install into whichever PC they choose. Boeing is still working with the software to make it adaptable to iPads and other tablets.

Before and after exercises, soldiers and troop commanders can see exactly where their units are located and how a potential exercise will play out. They can see a 3-D lay out of buildings and virtual battlefields. With a touch of the finger they can move units much like they did on a sand table. Commanders can even map fires and simulate entire exercise progressions, Irwin said.

Soldiers at Fort Sill, Okla., have already started training with the Virtual Mission Board. The Army has bought two boards for Fort Sill, one for Ft. Bragg, N.C., and one for Fort Lee, Va.. The Army is in the process of buying another one for Fort Lee, two for Fort Eustis, Va., one for Fort Rucker, Ala., five for Fort McCoy, Wisc., and one for the Pennsylvania National Guard. The Marine Corps has shown interest, but has yet to buy one, Irwin said.

For the same reason the Virtual Mission Board works as a training tool, Irwin can see Army units using it in deployed locations. Rather than using paper maps or Power Point slides before missions, a commander could outline an upcoming mission on the Virtual Mission Board.

The Army first started using the Virtual Mission Board in 2010. The potential use in combat is a new development.

At the most recent NIE this Spring, the Army tested the Command Tactical Vision touch screen mapping program built by Ringtail, a small company based in Austin, Texas. Soldiers and commanders raved about how easy it was to visualize the battlefield using the large touch screen map and the manner it condensed information that typically required four to five screens at a TOC.

Army and SOCOM leaders have already provided feedback on how Boeing could improve the board. Commanders asked Boeing to include a tool that measures a specific plot of land simply by tracing it with your finger. Boeing agreed and has made the adjustment.

“We’re always looking to make it better,” Irwin said.

From Boeing web site including video:

http://www.boeing.com/Features/2012/07/bds_vmb_07_23_12.html

High Tech, high-touch training: Virtual Mission Board

By Robert Sterling

The Virtual Mission Board

The Virtual Mission Board is helping change the way the U.S. Army trains.

A deployable, 55-inch touch-screen display system, the VMB operates the same as a smart phone or tablet. With colorful 3D graphics, the board can recreate terrains and cityscapes exactly as they appear in reality.

The board replaces the need for paper maps and elaborate models that often required an entire room to display. Participants are immersed in a virtual representation of the training environment before they ever step foot on the battlefield.

For instance, soldiers practicing "fires training" can input artillery shell trajectories into the board and quickly assess how an intervening hill or other impediment could hinder the mission. They can also evaluate how artillery might affect intervening air support.

The VMB, currently in use at Fort Sill, Okla., and other bases around the country, is not limited to military applications. The deployable, touch-screen board’s planning, tracking and review capabilities make it a useful device for training and security in various buildings and airports.




 
The Marine Corps has shown interest, but has yet to buy one, Irwin said.

They'll just wait until the Army throws them out for something new.......then they get them for free.... ;D
 
Some very out of the box thinking by the University of Guelph. While there isn't a definite correlation between gut bacteria and diseases like Autism, diabetes or obesity, there are some tenuous links which need to be explored. If this is a valid hypothesis, then you can imagine pmeds handing out packages of probiotic youghurt to forstall various diseases. Going farther on a limb, I would be very interested to see if there is a systemic difference between the gut bacteria of ordinary people and genius level people or Olympic level atheletes. A relatively simple means of upgrading the potential of recruits would then be possible if such a link could be established and verified:

http://atguelph.uoguelph.ca/2012/07/gut-bacteria-may-hold-key-to-autism/

Gut Bacteria May Hold Key to Autism
Mother of autistic son finds open minds at U of G
BY ANDREW VOWLES
FRIDAY, JULY 13, 2012

From left: Emma Allen-Vercoe, Sydney Finegold and Ellen Bolte
Ellen Bolte couldn’t believe what she was hearing. This past winter, the 53-year-old mom of four from suburban Chicago was making her first-ever visit to the University of Guelph. And what she was learning from researchers here sounded like hope.

It had been nearly two decades since Bolte had begun investigating possible links between gut bacteria and autism, spurred by her son’s debilitating experience with the disease.

Over the years she’d encountered plenty of skeptical doctors and scientists in the United States who refused to countenance a gut-brain connection – let alone a theory being pushed by someone lacking a formal background in either medicine or research.

Now she was at Guelph, and she was hearing something that “blew me away.”

Speaking over the phone early this summer from her home in New Lenox, Illinois, she says, “I was finally at an academic environment that was not just tolerating this possible gut-brain connection with autism but was excited about the research. I almost couldn’t wrap my head around the excitement I felt.”

In turn, her visit last February has helped to spur on Guelph projects to develop a vaccine against a potentially nasty human gastrointestinal (GI) bug and to explore possible connections between gut bacteria and autism.

Autism cases have increased almost six-fold over the past 20 years, and scientists don’t know why. Although many experts point to environmental factors, others have focused on the human gut. About 70 per cent of children with autism also have severe gastrointestinal symptoms.

Until this year, U of G chemistry professor Mario Monteiro hadn’t been thinking about autism.

He has spent five years studying Clostridium difficile, a microbe that causes GI symptoms, including diarrhea. The superbug can infect patients after antibiotics kill healthy gut bacteria.

He is working with Stellar Biotechnologies Inc. in California to develop his C. diff. vaccine that would target complex polysaccharides, or sugars, on the surface of the bug.

Monteiro’s lab has now discovered the polysaccharide target for a carbohydrate-based vaccine against another gut bug called Clostridium bolteae.

“Based on our experience with our polysaccharide C. diff. vaccine, we are confident that we can apply the same approach to create a vaccine to control diarrhea caused by C. bolteae and perhaps control autism-related symptoms,” he says.

For his studies, he used bacteria grown by Guelph microbiologist Emma Allen-Vercoe and her PhD student Mike Toh.

As a professor in Molecular and Cellular Biology, Allen-Vercoe has become an expert in culturing hard-to-grow species of bugs. This past spring, she co-authored a paper about a global project to identify and catalogue the genetic material of all microbes on and in the human body.

Allen-Vercoe says there’s more to C. bolteae than its potential role in gastrointestinal disorders. Some researchers believe toxins produced by gut bacteria, including this species, may be associated with autism symptoms. C. bolteae often shows up in higher numbers in the GI tracts of autistic children than in those of healthy kids.

She cautions that no one has yet shown that specific GI bacteria cause mental disorders, although research has shown that gut microbiota can affect mood and behaviour.

“C. bolteae is associated with autism, but this is not the same as saying that it is a cause of autism,” she says. “Much more work will be needed to show any connection. The availability of a vaccine that could be used in animal studies, for example, will greatly help us to determine the importance of C. bolteae in disease.

She says researchers need to look more closely at these microbes and links among behaviour, diet and gut health.

She is now looking for the same signature bugs in a group of autistic children.


Brittany Pequegnat and Mario Monteiro
In Monteiro’s lab, master’s student Brittany Pequegnat says she’s excited about possible autism connections.

“I like the idea of improving people’s quality of life,” says Pequegnat, who studied applied pharmaceutical chemistry at Guelph for her undergrad. She hopes to pursue vaccine research that might help in fighting gastrointestinal symptoms in autistic kids.

Allen-Vercoe and Monteiro have also worked together on Desulfovibrio, another microbe associated with both gut disease and autism.

Among the proponents of the so-called “bacterial theory” of autism is Sydney Finegold, a medical researcher at the University of California, Los Angeles. Last year Allen-Vercoe attended his 90th birthday party, where she met Bolte.

By then, Bolte had worked with Finegold in an unlikely collaboration rooted in her youngest son’s experience with autism.

Andrew Bolte, now 20, was about 18 months old when he developed regressive autism, which accounts for about 25 to 30 per cent of cases of autism. Before that, he had developed normally.

For two months before developing autism, he had received numerous doses of antibiotics for recurrent ear infections. Along with the autism came severe GI symptoms.

His case spurred Bolte to investigate possible links between antibiotic-related disruptions to gut microflora and autism. A self-taught computer programmer, she had no medical or scientific training.

In 1998, she published a paper in the peer-reviewed journal Medical Hypotheses, proposing connections between regressive autism and neurotoxins produced by pathogenic Clostridium in the gut.

She has since co-authored two more papers, including one about a medical trial using oral vancomycin – an antibiotic used against gut Clostridium species – to treat autism symptoms in children, including her son. Her co-authors included Finegold and Richard Sandler, a pediatric gastroenterologist at Rush Children’s Hospital in Chicago.

In a 2003 paper, Finegold and other researchers named a new species of gut bug, Clostridium bolteae, to recognize Bolte’s insights.

Bolte had begun investigating probiotics and fecal transplants when she met Allen-Vercoe last year. The Guelph microbiologist talked about her own research interest in potential supplements and treatments to restore healthy gut bugs (http://atguelph.uoguelph.ca/2012/06/bacteria-hold-key-to-better-health/).

Recalling their conversation, Bolte says, “She started talking at Dr. Finegold’s party about what she was doing. It was everything I had dreamed of – a complex human probiotic. This is the groundbreaking research that needs to take place in order for a product like this to come to market.

Earlier this year, Bolte visited Guelph to meet with Allen-Vercoe, Monteiro and other researchers. She brought her daughter, Erin, 22, who this year completed a biochemistry degree at the University of Notre Dame.

Erin plans to become a doctor and medical researcher. Before that, she hopes to learn about microbiology as a grad student in Allen-Vercoe’s lab.

She’s applied to Guelph. But as of late June, she needed to find enough money to pay for international studies.

“I was completely blown away by how much everybody works together at Guelph,” says Erin.

Ultimately, she hopes to study the bacterial theory of autism herself. “Autism is the focus to me because I’ve grown up with it.”

Allen-Vercoe was among international scientists featured in a documentary called “The Autism Enigma,” aired last year on David Suzuki’s The Nature of Things. The show will re-air July 26 at 8 p.m. on CBC TV.
 
Thucydides said:
A relatively simple means of upgrading the potential of recruits would then be possible if such a link could be established and verified:

Based on the quality of recruit product we see on this site, I don't think there's enough yogurt in the world to give them an upgrade. ;D
 
Some more on scramjet technology.

Imagine flying from New York to London in under an hour
By Mike Mount, CNN Senior National Security Producer

Perhaps Han Solo said it best in Star Wars when, describing his hyper-fast smuggling spaceship the Millennium Falcon, he said, "It may not look like much, but it's got it where it counts."

While the Air Force might take exception to being likened to the Falcon, in reality the platypus-nosed X-51A Waverider hypersonic flight test vehicle really doesn't look like much. But it definitely has it where it counts.

On Tuesday, the unmanned 25-foot-long vehicle will be dropped off of the wing of a converted B-52 bomber off the California coast and try to fly for 300 seconds at science fiction-like speeds of Mach 6, over 4,500 mph - fast enough to fly from New York to London in less than an hour.


It is the Pentagon's latest test as it studies the possibilities of hypersonic flight, defined as moving at speeds of Mach 5 (about 3,400 mph) and above without leaving the atmosphere. The technology could eventually bring missiles or airplanes to the other side of the planet in minutes instead of hours.

The Air Force and the Pentagon are not saying much about Tuesday's test, but the military could use such technology for reconnaissance aircraft, cruise missile-like weapons or vehicles that could carry people or cargo so fast adversaries would not have time to react, according to military analysts.

The Air Force conceived the X-51A program in 2004 and, according to the military analysis website Globalsecurity.org, the service has spent $140 million on the Waverider system. The Air Force will not disclose the actual cost of the program.

Long like a missile and with just a few fins in the rear, the Boeing-built aircraft is not designed as a bed for a weapon, according to the Air Force, but it is testing the technology to build future weapons around.

Past Waverider flights have come with mixed results. In May 2010, the Waverider made its first flight at 3,500 mph for 143 seconds before a malfunction caused the test to shut down early.

A June 2011 test also was shutdown early but did collect some data for the Air Force.

If all goes as planned, the flight Tuesday will end with a dive into the Pacific; there is no intent to recover the aircraft. The Air Force says the program was designed for each vehicle to be destroyed at the end of its flight test because of the cost that would be involved in recovering them. Data is fed back to evaluators during the test.

The Pentagon considers hypersonic flight the new stealth. The technology could move reconnaissance or bomber aircraft at high altitudes and speeds that put them far out of the reach of surface-to-air missiles or other anti-aircraft fire. The kind of speeds the X-51A is able to reach cannot be achieved with current jet-powered technology.

The aircraft uses "scramjet" technology, an engine with virtually no moving parts. It uses oxygen from the atmosphere for its engines, as opposed to carrying large fuel tanks that rockets require, making it a more efficient vehicle for military or commercial purposes.

Additionally, because of the high speeds the vehicle is also able to ride on the shockwave it creates at six times the speed of sound, increasing efficiency, according to an Air Force factsheet on the X-51A. It says that is also the genesis of the vehicle's nickname, the Waverider.

The Pentagon's high-technology research group, the Defense Advanced Research Projects Agency, or DARPA, says getting aircraft to speeds of Mach 20 - which would enable the military to get anywhere in the world in under an hour - is an area of research where significant scientific advancements have eluded researchers for decades.

The Pentagon says it is studying this technology as countries have made advances in thwarting stealth technologies the U.S military has in its arsenal.

"That strategic advantage is threatened as other nations' abilities in stealth and counter-stealth improve," according to DARPA website. "Restoring that battle space advantage requires advanced speed, reach and range. Hypersonic technologies have the potential to provide the dominance once afforded by stealth to support a range of varied future national security missions."

The military could use it in two realms, according to Dan Wasserbly, the Americas editor of IHS/Jane's, a military analysis publication.

"They could use it to develop cruise missile-like weapons that could reach a target on the other side of the planet in minutes instead of hours, as well as developing aircraft which could put a quick-reaction force on a far-off battleground within hours instead of days," Wasserbly said.

The Air Force has said that by 2016 it would like to have a working weapon flying with hypersonic technology. But with the program budgeted only though this Tuesday's test, it is unclear when anything with hypersonic technology could be fielded, according to Wasserbly.

The Air Force made four of the X-51A test vehicles. Tuesday's test will be the third and possibly last test, according to Air Force spokesman Daryl Mayer.

"The Air Force will review the data from this mission and assess what will come next," he said.

The Pentagon has also been studying other hypersonic technology, including 2010 and 2011 flight tests of the Falcon Hypersonic Test Vehicle (HTV-2) capable of reaching Mach 20, approximately 13,000 mph, according to DARPA.

Both of those tests ended with the aircraft crashing before the tests were complete.

So even after the Air Force evaluates the results of the Tuesday test, it will be hard to know when the military will start launching troops from the U.S. to a far-flung combat zone in minutes.


http://security.blogs.cnn.com/2012/08/14/imagine-flying-from-new-york-to-london-in-under-an-hour/?hpt=hp_c1
 
The Navy wants robots to look for enemy submarines:

http://www.darpa.mil/NewsEvents/Releases/2012/08/16.aspx

UNMANNED SUB-HUNTER TO QUELL A SILENT THREAT

August 16, 2012

DARPA autonomous surface vessel to track and follow enemy subs for months

The growing number of adversaries able to build and operate quiet diesel electric submarines is a national security threat that affects U.S. and friendly naval operations around the world. To address this emerging threat, DARPA recently awarded a contract for Phases 2-4 of its Anti-Submarine Warfare (ASW) Continuous Trail Unmanned Vessel (ACTUV) program to Science Applications International Corporation, McLean, Va.

During Phases 2-4 the ACTUV program will attempt to design, construct and demonstrate an unmanned vessel that tracks quiet diesel electric submarines for months at a time spanning thousands of kilometers of ocean with minimal human input.

“Key features and technology for the vessel include advanced software, robust autonomy for safe operations in accordance with maritime laws, and innovative sensors to continuously track the quietest of submarine targets,” said Scott Littlefield, DARPA program manager.

If successful, ACTUV would create a technological strategic advantage against the burgeoning quiet submarine threat and reduce manpower and other costs associated with current ASW trail operations.

“Our goal is to transition an operational game-changer to the Navy,” said Littlefield. “This should create an asymmetry to our advantage, negating a challenging submarine threat at one-tenth their cost of building subs. The program also establishes foundational technologies for future unmanned naval systems.”

During Phase 1 the program refined and validated the system concept, completing risk reduction testing associated with submarine tracking sensors and maritime autonomy. Operational prototype at-sea testing is expected in mid-2015.
 
Remember the discussion upthread about gigapixel cameras and the issue of storage and bandwidth? The bandwidth issue seems to have been cracked here, and now the storage of vast amounts of data seems to have a solution as well:

http://www.extremetech.com/extreme/134672-harvard-cracks-dna-storage-crams-700-terabytes-of-data-into-a-single-gram

Harvard cracks DNA storage, crams 700 terabytes of data into a single gram
By Sebastian Anthony on August 17, 2012 at 10:22 am198 Comments

A bioengineer and geneticist at Harvard’s Wyss Institute have successfully stored 5.5 petabits of data — around 700 terabytes — in a single gram of DNA, smashing the previous DNA data density record by a thousand times.

The work, carried out by George Church and Sri Kosuri, basically treats DNA as just another digital storage device. Instead of binary data being encoded as magnetic regions on a hard drive platter, strands of DNA that store 96 bits are synthesized, with each of the bases (TGAC) representing a binary value (T and G = 1, A and C = 0).

To read the data stored in DNA, you simply sequence it — just as if you were sequencing the human genome — and convert each of the TGAC bases back into binary. To aid with sequencing, each strand of DNA has a 19-bit address block at the start (the red bits in the image below) — so a whole vat of DNA can be sequenced out of order, and then sorted into usable data using the addresses.

Scientists have been eyeing up DNA as a potential storage medium for a long time, for three very good reasons: It’s incredibly dense (you can store one bit per base, and a base is only a few atoms large); it’s volumetric (beaker) rather than planar (hard disk); and it’s incredibly stable — where other bleeding-edge storage mediums need to be kept in sub-zero vacuums, DNA can survive for hundreds of thousands of years in a box in your garage.

It is only with recent advances in microfluidics and labs-on-a-chip that synthesizing and sequencing DNA has become an everyday task, though. While it took years for the original Human Genome Project to analyze a single human genome (some 3 billion DNA base pairs), modern lab equipment with microfluidic chips can do it in hours. Now this isn’t to say that Church and Kosuri’s DNA storage is fast — but it’s fast enough for very-long-term archival.

Just think about it for a moment: One gram of DNA can store 700 terabytes of data. That’s 14,000 50-gigabyte Blu-ray discs… in a droplet of DNA that would fit on the tip of your pinky. To store the same kind of data on hard drives — the densest storage medium in use today — you’d need 233 3TB drives, weighing a total of 151 kilos. In Church and Kosuri’s case, they have successfully stored around 700 kilobytes of data in DNA — Church’s latest book, in fact — and proceeded to make 70 billion copies (which they claim, jokingly, makes it the best-selling book of all time!) totaling 44 petabytes of data stored.

Looking forward, they foresee a world where biological storage would allow us to record anything and everything without reservation. Today, we wouldn’t dream of blanketing every square meter of Earth with cameras, and recording every moment for all eternity/human posterity — we simply don’t have the storage capacity. There is a reason that backed up data is usually only kept for a few weeks or months — it just isn’t feasible to have warehouses full of hard drives, which could fail at any time. If the entirety of human knowledge — every book, uttered word, and funny cat video — can be stored in a few hundred kilos of DNA, though… well, it might just be possible to record everything (hello, police state!)

It’s also worth noting that it’s possible to store data in the DNA of living cells — though only for a short time. Storing data in your skin would be a fantastic way of transferring data securely…

Read: Biological computer can decrypt images stored in DNA, Living organ-on-a-chip could soon replace animal testing

Research paper: DOI: 10.1126/science.1226355

Of course a DNA based storage media isn't as fast as an electronic or photonic one, (at least not with current technologies), but with the small size of the storage media, it seems likely that some sort of memory buffer could be attached; the device would be like an external hard drive with some sort of read/write mechanism to pull information from the DNA and rapidly put it into the computing device itself.
 
Analog computers have been around for a long time, but digital computers have many advantages (particularly in being rapidly programable). If this research pays off, the benefit to us would be computer devices which use much less power, resulting in soldiers having to carry fewer batteries, battery chargers, mobile generators etc. The logistical chain fallout could be immense:

http://www.wired.com/wiredenterprise/2012/08/upside/

Darpa Has Seen the Future of Computing … And It’s Analog
By Robert McMillanEmail Author 08.22.12 6:30 AM
| Edit


How would non-digital chips work? Darpa paints a picture. Image: Darpa


By definition, a computer is a machine that processes and stores data as ones and zeroes. But the U.S. Department of Defense wants to tear up that definition and start from scratch.

Through its Defense Advanced Research Projects Agency (Darpa), the DoD is funding a new program called UPSIDE, short for Unconventional Processing of Signals for Intelligent Data Exploitation. Basically, the program will investigate a brand-new way of doing computing without the digital processors that have come to define computing as we know it.

The aim is to build computer chips that are a whole lot more power-efficient than today’s processors — even if they make mistakes every now and then.

The way Darpa sees it, today’s computers — especially those used by mobile spy cameras in drones and helicopters that have to do a lot of image processing — are starting to hit a dead end. The problem isn’t processing. It’s power, says Daniel Hammerstrom, the Darpa program manager behind UPSIDE. And it’s been brewing for more than a decade.

“One of the things that’s happened in the last 10 to 15 years is that power-scaling has stopped,” he says. Moore’s law — the maxim that processing power will double every 18 months or so — continues, but battery lives just haven’t kept up. “The efficiency of computation is not increasing very rapidly,” he says.

Hammerstom, who helped build chips for Intel back in the 1980s, wants the UPSIDE chips to do computing in a whole different way. He’s looking for an alternative to straight-up boolean logic, where the voltage in a chip’s transistor represents a zero or a one. Hammerstrom wants chipmakers to build analog processors that can do probabilistic math without forcing transistors into an absolute one-or-zero state, a technique that burns energy.

It seems like a new idea — probabilistic computing chips are still years away from commercial use — but it’s not entirely. Analog computers were used in the 1950s, but they were overshadowed by the transistor and the amazing computing capabilities that digital processors pumped out over the past half-century, according to Ben Vigoda, the general manager of the Analog Devices Lyric Labs group.

“The people who are just retiring from university right now can remember programming analog computers in college,” says Vigoda. “It’s been a long time since we really questioned the paradigm that we’re using.”

Probabilistic computing has been picking up over the past decade, Vigoda says, and it’s being spurred now by Darpa’s program. “They bringing an emerging technology into the limelight,” he says.

Darpa’s 54-month program will run in two phases. During the first companies will build chips using probabilistic techniques. During the second, they will build mobile imaging systems using the chips. Hammerstein expects the systems to be faster and “orders of magnitude more power-efficient.”

“There’s a sense that it’s time to revisit some of these issues,” says Darpa’s Hammerstrom. “And this is what Darpa does. We look around and we say, ‘This is a place and a time where we could make a difference.’”

Hammerstrom wouldn’t say how much Darpa is investing in UPSIDE, but he described it as a “moderate-sized Darpa program.”

Six years ago, Vigoda started a company called Lyric Semiconductor to build a “probability processor” that can do the work of many chips. Lyric was acquired by Analog Devices, a maker of chips for medical, cellular, industrial and consumer systems, and Vigoda says that the probability processor could be used in any of those markets.


The same photo using traditional digital techniques (left) and probabilistic imaging systems. Photos: Rice University

Probabilistic computing has two basic promises: one is to open the door to low-power, high-performance computing, especially in areas where the answer doesn’t have to be completely perfect — image rendering for example.

That’s what researchers at Rice university hit at earlier this year when they designed a low-power chip that uses probabilistic computing techniques to do energy-efficient, if occasionally inexact, calculations.

Another promise is to build new types of chips that can solve some of the complex data analysis problems that are on the cutting edge of today’s computer science.

“We’re using a few percent of the U.S.’s electricity bill on server farms and we can only do very basic machine-learning,” says Vigoda. “We’re just doing really really simple stuff because we don’t have the compute power to do it. One of the ways to fix this is to design chips that do machine-learning.”
 
Wood, the wonder material:

http://www.newscientist.com/article/mg21528786.100-why-wood-pulp-is-worlds-new-wonder-material.html?full=true&print=true

Why wood pulp is world's new wonder material
Updated 11:23 24 August 2012 by Will Ferguson
Magazine issue 2878. Subscribe and save
For similar stories, visit the Nanotechnology Topic Guide

Soon to be car parts? (Image: Jim Zuckerman/Corbis)
THE hottest new material in town is light, strong and conducts electricity. What's more, it's been around a long, long time.

Nanocrystalline cellulose (NCC), which is produced by processing wood pulp, is being hailed as the latest wonder material. Japan-based Pioneer Electronics is applying it to the next generation of flexible electronic displays. IBM is using it to create components for computers. Even the US army is getting in on the act, using it to make lightweight body armour and ballistic glass.

To ramp up production, the US opened its first NCC factory in Madison, Wisconsin, on 26 July, marking the rise of what the US National Science Foundation predicts will become a $600 billion industry by 2020.

So why all the fuss? Well, not only is NCC transparent but it is made from a tightly packed array of needle-like crystals which have a strength-to-weight ratio that is eight times better than stainless steel. Even better, it's incredibly cheap.

"It is the natural, renewable version of a carbon nanotube at a fraction of the price," says Jeff Youngblood of Purdue University's NanoForestry Institute in West Lafayette, Indiana.

The $1.7 million factory, which is owned by the US Forest Service, will produce two types of NCC: crystals and fibrils.

Production of NCC starts with "purified" wood, which has had compounds such as lignin and hemicellulose removed. It is then milled into a pulp and hydrolysed in acid to remove impurities before being separated and concentrated as crystals into a thick paste that can be applied to surfaces as a laminate or processed into strands, forming nanofibrils. These are hard, dense and tough, and can be forced into different shapes and sizes. When freeze-dried, the material is lightweight, absorbent and good at insulating.

"The beauty of this material is that it is so abundant we don't have to make it," says Youngblood. "We don't even have to use entire trees; nanocellulose is only 200 nanometres long. If we wanted we could use twigs and branches or even sawdust. We are turning waste into gold."

The US facility is the second pilot production plant for cellulose-based nanomaterials in the world. The much larger CelluForce facility opened in Montreal, Canada, in November 2011 and is now producing a tonne of NCC a day.

Theodore Wegner, assistant director of the US factory, says it will be producing NCC on a large scale. It will be sold at just several dollars a kilogram within a couple of years. He says it has taken this long to unlock the potential of NCC because the technology to explore its properties, such as electron scanning microscopes, only emerged in the last decade or so.

NCC will replace metal and plastic car parts and could make nonorganic plastics obsolete in the not-too-distant future, says Phil Jones, director of new ventures and disruptive technologies at the French mineral processing company IMERYS. "Anyone who makes a car or a plastic bag will want to get in on this," he says.

In addition, the human body can deal with cellulose safely, says Jones, so NCC is less dangerous to process than inorganic composites. "The worst thing that could happen is a paper cut," he says.
 
We're getting closer to the day:

"It can't be bargained with. It can't be reasoned with. It doesn't feel pity, or remorse, or fear. And it absolutely will not stop, ever"

http://spectrum.ieee.org/automaton/robotics/military-robots/boston-dynamics-cheetah-robot-now-faster-than-fastest-human

Boston Dynamics' Cheetah Robot Now Faster than Fastest Human
POSTED BY: EVAN ACKERMAN  /  WED, SEPTEMBER 05, 2012

Boston Dynamics' Cheetah robot has just set a new record for legged robots by sprinting at 28.3 mph. This, incidentally, is also faster than Olympic (human) champion Usain Bolt, who set the world record for the 100 meter dash with a speed of 27.8 mph back in 2009. Yes, this means that now there is officially no escape from a robot cheetah on a treadmill. You've been warned.

To boost Cheetah's speed, Boston Dynamics "refined the control algorithms that coordinate the robot's leg and back motions and increased the installed power." Making the robot faster isn't just a matter of cranking up the power and increasing leg speed, but rather involves a biologically-inspired choreography of interactions between the robot's feet, legs, and back.

Cheetah, of course, is not running outdoors, where it would have to deal with wind resistance. It's also relying on off-board power, and without that boom in place, it would likely fall over, meaning that if you find yourself being chased by the current version of this robot, a simple movement to the left or right should stymie it completely whether you're Usain Bolt or not. With this in mind, Boston Dynamics concedes that "Bolt is still the superior athlete," but perhaps not for long: this is by no means the final version of Cheetah, and Boston Dynamics is currently creating a new version of the robot called WildCat that will be running outdoors as of early next year.

This robot will be untethered (looks like it's probably powered by a gasoline engine like AlphaDog) and it will also be able to, you know, turn. Boston Dynamics isn't stopping at 28.3 mph, either: we know they've had their eye on 50 mph for a while, and the top speed of a biological cheetah (approximately 70 mph) may eventually be within reach. We're not sure when this will be, but considering that Cheetah made it from a top speed of 18 mph in March of this year to 28 mph less than five months later, we can't imagine it'll be long enough for us to get comfortable with the idea of being chased down (and possibly eaten) by a robotic quadruped.

http://www.youtube.com/watch?v=chPanW0QWhA&feature=player_embedded
 
Ever thought about how Google makes their maps? This multi dimentional databasing of maps puts things like Arcview to shame. Graphics on link:

http://www.theatlantic.com/technology/archive/2012/09/how-google-builds-its-maps-and-what-it-means-for-the-future-of-everything/261913/

How Google Builds Its Maps—and What It Means for the Future of Everything
By Alexis C. Madrigal

Sep 6 2012, 3:27 PM ET 112

An exclusive look inside Ground Truth, the secretive program to build the world's best accurate maps.

Behind every Google Map, there is a much more complex map that's the key to your queries but hidden from your view. The deep map contains the logic of places: their no-left-turns and freeway on-ramps, speed limits and traffic conditions. This is the data that you're drawing from when you ask Google to navigate you from point A to point B -- and last week, Google showed me the internal map and demonstrated how it was built. It's the first time the company has let anyone watch how the project it calls GT, or "Ground Truth," actually works.

Google opened up at a key moment in its evolution. The company began as an online search company that made money almost exclusively from selling ads based on what you were querying for. But then the mobile world exploded. Where you're searching from has become almost as important as what you're searching for. Google responded by creating an operating system, brand, and ecosystem in Android that has become the only significant rival to Apple's iOS.

And for good reason. If Google's mission is to organize all the world's information, the most important challenge -- far larger than indexing the web -- is to take the world's physical information and make it accessible and useful.

"If you look at the offline world, the real world in which we live, that information is not entirely online," Manik Gupta, the senior product manager for Google Maps, told me. "Increasingly as we go about our lives, we are trying to bridge that gap between what we see in the real world and [the online world], and Maps really plays that part."

This is not just a theoretical concern. Mapping systems matter on phones precisely because they are the interface between the offline and online worlds. If you're at all like me, you use mapping more than any other application except for the communications suite (phone, email, social networks, and text messaging).

Google is locked in a battle with the world's largest company, Apple, about who will control the future of mobile phones. Whereas Apple's strengths are in product design, supply chain management, and retail marketing, Google's most obvious realm of competitive advantage is in information. Geo data -- and the apps built to use it -- are where Google can win just by being Google. That didn't matter on previous generations of iPhones because they used Google Maps, but now Apple's created its own service. How the two operating systems incorporate geo data and present it to users could become a key battleground in the phone wars.

But that would entail actually building a better map.

***

The office where Google has been building the best representation of the world is not a remarkable place. It has all the free food, ping pong, and Google Maps-inspired Christoph Niemann cartoons that you'd expect, but it's still a low-slung office building just off the 101 in Mountain View in the burbs.

I was slated to meet with Gupta and the engineering ringleader on his team, former NASA engineer Michael Weiss-Malik, who'd spent his 20 percent time working on Google Mars, and Nick Volmar, an "operator" who actually massages map data.

"So you want to make a map," Weiss-Malik tells me as we sit down in front of a massive monitor. "There are a couple of steps. You acquire data through partners. You do a bunch of engineering on that data to get it into the right format and conflate it with other sources of data, and then you do a bunch of operations, which is what this tool is about, to hand massage the data. And out the other end pops something that is higher quality than the sum of its parts."

This is what they started out with, the TIGER data from the US Census Bureau (though the base layer could and does come from a variety of sources in different countries).
US-before.jpeg

On first inspection, this data looks great. The roads look like they are all there and you've got the freeways differentiated. This is a good map to the untrained eye. But let's look closer. There are issues where the digital data does not match the physical world. I've circled a few obvious ones below.

usbefore2.jpg
And that's just from comparing the map to the satellite imagery. But there are also a variety of other tools at Google's disposal. One is bringing in data from other sources, say the US Geological Survey. But Google's Ground Truthers can also bring another exclusive asset to bear on the maps problem: the Street View cars' tracks and imagery. In keeping with Google's more-data-is-better-data mantra, the maps team, largely driven by Street View, is publishing more imagery data every two weeks than Google possessed total in 2006.*

Let's step back a tiny bit to recall with wonderment the idea that a single company decided to drive cars with custom cameras over every road they could access. Google is up to five million miles driven now. Each drive generates two kinds of really useful data for mapping. One is the actual tracks the cars have taken; these are proof-positive that certain routes can be taken. The other are all the photos. And what's significant about the photographs in Street View is that Google can run algorithms that extract the traffic signs and can even paste them onto the deep map within their Atlas tool. So, for a particularly complicated intersection like this one in downtown San Francisco, that could look like this:

us_signage.jpeg

Google Street View wasn't built to create maps like this, but the geo team quickly realized that computer vision could get them incredible data for ground truthing their maps. Not to detour too much, but what you see above is just the beginning of how Google is going to use Street View imagery. Think of them as the early web crawlers (remember those?) going out in the world, looking for the words on pages. That's what Street View is doing. One of its first uses is finding street signs (and addresses) so that Google's maps can better understand the logic of human transportation systems. But as computer vision and OCR improve, any word that is visible from a road will become a part of Google's index of the physical world.

Later in the day, Google Maps VP Brian McClendon put it like this: "We can actually organize the world's physical written information if we can OCR it and place it," McClendon said. "We use that to create our maps right now by extracting street names and addresses, but there is a lot more there."
 

More like what? "We already have what we call 'view codes' for 6 million businesses and 20 million addresses, where we know exactly what we're looking at," McClendon continued. "We're able to use logo matching and find out where are the Kentucky Fried Chicken signs ... We're able to identify and make a semantic understanding of all the pixels we've acquired. That's fundamental to what we do."

For now, though, computer vision transforming Street View images directly into geo-understanding remains in the future. The best way to figure out if you can make a left turn at a particular intersection is still to have a person look at a sign -- whether that's a human driving or a human looking at an image generated by a Street View car.

There is an analogy to be made to one of Google's other impressive projects: Google Translate. What looks like machine intelligence is actually only a recombination of human intelligence. Translate relies on massive bodies of text that have been translated into different languages by humans; it then is able to extract words and phrases that match up. The algorithms are not actually that complex, but they work because of the massive amounts of data (i.e. human intelligence) that go into the task on the front end.

Google Maps has executed a similar operation. Humans are coding every bit of the logic of the road onto a representation of the world so that computers can simply duplicate (infinitely, instantly) the judgments that a person already made.

This reality is incarnated in Nick Volmar, the operator who has been showing off Atlas while Weiss-Malik and Gupta explain it. He probably uses twenty-five keyboard shortcuts switching between types of data on the map and he shows the kind of twitchy speed that I associate with long-time designers working with Adobe products or professional Starcraft players. Volmar has clearly spent thousands of hours working with this data. Weiss-Malik told me that it takes hundreds of operators to map a country. (Rumor has it many of these people work in the Bangalore office, out of which Gupta was promoted.)

The sheer amount of human effort that goes into Google's maps is just mind-boggling. Every road that you see slightly askew in the top image has been hand-massaged by a human. The most telling moment for me came when we looked at couple of the several thousand user reports of problems with Google Maps that come in every day. The Geo team tries to address the majority of fixable problems within minutes. One complaint reported that Google did not show a new roundabout that had been built in a rural part of the country. The satellite imagery did not show the change, but a Street View car had recently driven down the street and its tracks showed the new road perfectly.

Volmar began to fix the map, quickly drawing the new road and connecting it to the existing infrastructure. In his haste (and perhaps with the added pressure of three people watching his every move), he did not draw a perfect circle of points. Weiss-Malik and I detoured into another conversation for a couple of minutes. By the time I looked back at the screen, Volmar had redrawn the circle with perfect precision and upgraded a few other things while he was at it. The actions were impressively automatic. This is an operation that promotes perfectionism.

And that's how you get your maps to look this this:

US-after.jpeg

Some details are worth pointing out. In the top at the center, trails have been mapped out and coded as places for walking. All the parking lots have been mapped out. All the little roads, say, to the left of the small dirt patch on the right, have also been coded. Several of the actual buildings have been outlined. Down at the bottom left, a road has been marked as a no-go. At each and every intersection, there are arrows that delineate precisely where cars can and cannot turn.

Now imagine doing this for every tile on Google's map in the United States and 30 other countries over the last four years. Every roundabout perfectly circular, every intersection with the correct logic. Every new development. Every one-way street. This is a task of a nearly unimaginable scale. This is not something you can put together with a few dozen smart engineers.

I came away convinced that the geographic data Google has assembled is not likely to be matched by any other company. The secret to this success isn't, as you might expect, Google's facility with data, but rather its willingness to commit humans to combining and cleaning data about the physical world. Google's map offerings build in the human intelligence on the front end, and that's what allows its computers to tell you the best route from San Francisco to Boston.

It's probably better not to think of Google Maps as a thing like a paper map. Geographic information systems represent a jump from paper maps like the abacus to the computer. "I honestly think we're seeing a more profound change, for map-making, than the switch from manuscript to print in the Renaissance," University of London cartographic historian Jerry Brotton told the Sydney Morning Herald. "That was huge. But this is bigger."

The maps we used to keep folded in our glove compartments were a collection of lines and shapes that we overlaid with human intelligence. Now, as we've seen, a map is a collection of lines and shapes with Nick Volmar's (and hundreds of others') intelligence encoded within.

It's common when we discuss the future of maps to reference the Borgesian dream of a 1:1 map of the entire world. It seems like a ridiculous notion that we would need a complete representation of the world when we already have the world itself. But to take scholar Nathan Jurgenson's conception of augmented reality seriously, we would have to believe that every physical space is, in his words, "interpenetrated" with information. All physical spaces already are also informational spaces. We humans all hold a Borgesian map in our heads of the places we know and we use it to navigate and compute physical space. Google's strategy is to bring all our mental maps together and process them into accessible, useful forms.

Their MapMaker product makes that ambition clear. Project managed by Gupta during his time in India, it's the "bottom up" version of Ground Truth. It's a publicly accessible way to edit Google Maps by adding landmarks and data about your piece of the world. It's a way of sucking data out of human brains and onto the Internet. And it's a lot like Google's open competitor, Open Street Map, which has proven that it, too, can harness the crowd's intelligence.

As we slip and slide into a world where our augmented reality is increasingly visible to us off and online, Google's geographic data may become its most valuable asset. Not solely because of this data alone, but because location data makes everything else Google does and knows more valuable.

Or as my friend and sci-fi novelist Robin Sloan put it to me, "I maintain that this is Google's core asset. In 50 years, Google will be the self-driving car company (powered by this deep map of the world) and, oh, P.S. they still have a search engine somewhere."

Of course, they will always need one more piece of geographic information to make all this effort worthwhile: You. Where you are, that is. Your location is the current that makes Google's giant geodata machine run. They've built this whole playground as an elaborate lure for you. As good and smart and useful as it is, good luck resisting taking the bait.

* Due to a transcription error, an earlier version of this story stated that Google published 20PB of imagery data every two weeks.
 
Energy efficiency is very important. Using this new technology will allow more electrical energy to be harvested without mechanical or chemical steps (and the resulting weight and efficiency losses). A generator or hybrid vehicle would be a great military application, but even using this material in a furnace or hot water heater would also provide a useful suppliment for homes, bases and other fixed installations:

http://phys.org/news/2012-09-thermoelectric-material-world-electricity.html

September 19, 2012 Northwestern University scientists have developed a thermoelectric material that is the best in the world at converting waste heat to electricity.

This is very good news once you realize nearly two-thirds of energy input is lost as waste heat.

The material could signify a paradigm shift. The inefficiency of current thermoelectric materials has limited their commercial use. Now, with a very environmentally stable material that is expected to convert 15 to 20 percent of waste heat to useful electricity, thermoelectrics could see more widespread adoption by industry.

Possible areas of application include the automobile industry (much of gasoline's potential energy goes out a vehicle's tailpipe), heavy manufacturing industries (such as glass and brick making, refineries, coal- and gas-fired power plants) and places were large combustion engines operate continuously (such as in large ships and tankers).

Waste heat temperatures in these areas can range from 400 to 600 degrees Celsius (750 to 1,100 degrees Fahrenheit), the sweet spot for thermoelectrics use. The new material, based on the common semiconductor lead telluride, is the most efficient thermoelectric material known. It exhibits a thermoelectric figure of merit (so-called "ZT") of 2.2, the highest reported to date. Chemists, physicists, material scientists and mechanical engineers at Northwestern and Michigan State University collaborated to develop the material.

The study will be published Sept. 20 by the journal Nature.

"Our system is the top-performing thermoelectric system at any temperature," said Mercouri G. Kanatzidis, who led the research and is a senior author of the paper. "The material can convert heat to electricity at the highest possible efficiency. At this level, there are realistic prospects for recovering high-temperature waste heat and turning it into useful energy." Ads by Google Thermoelectric Products - Supplier of thermoelectric modules Peltier products - www.inbthermoelectric.com Kanatzidis is Charles E. and Emma H. Morrison Professor of Chemistry in Northwestern's Weinberg College of Arts and Sciences. He also holds a joint appointment at Argonne National Laboratory.

"People often ask, what is the energy solution?" said Vinayak P. Dravid, one of Kanatzidis' close collaborators. "But there is no unique solution—it's going to be a distributed solution. Thermoelectrics is not the answer to all our energy problems, but it is an important part of the equation." Dravid is the Abraham Harris Professor of Materials Science and Engineering at the McCormick School of Engineering and Applied Science and a senior author of the paper.

Other members of the team and authors of the Nature paper include Kanishka Biswas, a postdoctoral fellow in Kanatzidis' group; Jiaqing He, a postdoctoral member in Dravid's group; David N. Seidman, Walter P. Murphy Professor of Materials Science and Engineering at Northwestern; and Timothy P. Hogan, professor of electrical and computer engineering, at Michigan State University.

Even before the Northwestern record-setting material, thermoelectric materials were starting to get better and being tested in more applications. The Mars rover Curiosity is powered by lead telluride thermoelectrics (although it's system has a ZT of only 1, making it half as efficient as Northwestern's system), and BMW is testing thermoelectrics in its cars by harvesting heat from the exhaust system.

"Now, having a material with a ZT greater than two, we are allowed to really think big, to think outside the box," Dravid said. "This is an intellectual breakthrough." "Improving the ZT never stops—the higher the ZT, the better," Kanatzidis said. "We would like to design even better materials and reach 2.5 or 3. We continue to have new ideas and are working to better understand the material we have." The efficiency of waste heat conversion in thermoelectrics is governed by its figure of merit, or ZT. This number represents a ratio of electrical conductivity and thermoelectric power in the numerator (which need to be high) and thermal conductivity in the denominator (which needs to be low).

"It is hard to increase one without compromising the other," Dravid said. These contradictory requirements stalled the progress towards a higher ZT for many years, where it was stagnant at a nominal value of 1. Kanatzidis and Dravid have pushed the ZT higher and higher in recent years by introducing nanostructures in bulk thermoelectrics. In January 2011, they published a report in Nature Chemistry of a thermoelectric material with a ZT of 1.7 at 800 degrees Kelvin.

This was the first example of using nanostructures (nanocrystals of rock-salt structured strontium telluride) in lead telluride to reduce electron scattering and increase the energy conversion efficiency of the material. The performance of the new material reported now in Nature is nearly 30 percent more efficient than its predecessor. The researchers achieved this by scattering a wider spectrum of phonons, across all wavelengths, which is important in reducing thermal conductivity. "Every time a phonon is scattered the thermal conductivity gets lower, which is what we want for increased efficiency," Kanatzidis said.

A phonon is a quantum of vibrational energy, and each has a different wavelength. When heat flows through a material, a spectrum of phonons needs to be scattered at different wavelengths (short, intermediate and long). In this work, the researchers show that all length scales can be optimized for maximum phonon scattering with minor change in electrical conductivity. "We combined three techniques to scatter short, medium and long wavelengths all together in one material, and they all work simultaneously," Kanatzidis said.

"We are the first to scatter all three at once and at the widest spectrum known. We call this a panoscopic approach that goes beyond nanostructuring." "It's a very elegant design," Dravid said. In particular, the researchers improved the long-wavelength scattering of phonons by controlling and tailoring the mesoscale architecture of the nanostructured thermoelectric materials. This resulted in the world record of a ZT of 2.2. The successful approach of integrated all-length-scale scattering of phonons is applicable to all bulk thermoelectric materials, the researchers said. More information: The paper is titled "High-Performance Bulk Thermoelectrics With Hierarchical Architecture."

Read more at: http://phys.org/news/2012-09-thermoelectric-material-world-electricity.html#jCp
 
The use of micro inertial guidance systems will have a great many applications, both inside and outside the military. Being able to navigate with pinpoint precision without GPS will be another "killer app" in lots of situations.

http://www.darpa.mil/NewsEvents/Releases/2012/09/20.aspx

Microfabrication methods to help navigate a day without GPS

September 20, 2012

New techniques developed for smaller inertial sensors

Military missions of all types need extremely accurate navigation techniques to keep people and equipment on target. That is why the Military relies on GPS or, when GPS is unavailable, precise sensors for navigation. These sensors, such as gyroscopes that measure orientation, are bulky and expensive to fabricate. For example, a single gyroscope designed as an inertial sensor accurate enough for a precision missile can take up to 1 month to be hand assembled and cost up to $1 million. DARPA has made progress in developing less expensive fabrication methods for inertial sensors and is making them orders of magnitude smaller and less expensive.

DARPA is developing new fabrication techniques for microscale inertial sensors with the goal of creating enough accuracy to replace the large, expensive gyroscopes used today. This work is being done under the Microscale Rate Integrating Gyroscope (MRIG) effort of the Micro-Technology for Positioning, Navigation and Timing (Micro-PNT) program. During the recently completed first phase, MRIG focused on 3-D microfabrication methods using nontraditional materials, such as bulk metallic glasses, diamond and ultra-low expansion glass. Small 3-D structures such as toroids, hemispheres and wineglass-shaped structures were successfully fabricated, shifting away from the 2-D paradigm of current state-of-the-art microgyroscopes.

These microscale inertial sensors work like Foucault pendulums commonly found in museums. The swinging direction of the pendulum slowly changes as the Earth rotates. Instead of a swinging pendulum, microscale inertial sensors send out vibrations across the surface of a 3-D structure.  The precession of the standing wave is measured and any changes reflect a change in orientation. Among the several new fabrication methods created by DARPA to work with these microscale inertial sensors are:

Glass-blowing. Researchers developed fabrication methods that replicate traditional glass-blowing techniques at the microscale. The result is tiny 3-D wineglass-shaped inertial sensors. These sensors are symmetrical enough to have a frequency split approaching 10 hertz—a result never before achieved at this size and approaching levels of symmetry required for high-quality navigation devices.The frequency split is a measure to predict the symmetry—and thus accuracy—of the device. It is a measure of the difference between two different axes of elasticity. The greater the difference, the more imperfection is present, resulting in a less accurate sensor.

Blown quartz. Similar to glass blowing, quartz blowing can be used to make an even more symmetric structure. Researchers developed fabrication techniques needed to heat quartz to 1,700 degrees Celsius (a typical softening point for glass is about 800 degrees Celsius) and to then cool it rapidly. The fabrication can be performed in large quantity batches, producing hundreds of devices on a single wafer.

Atomic layering of diamond. Layering diamond over a blown structure or depositing CVD diamond in a micro-well on the substrate have been shown to be effective, promising methods for creating highly symmetric, accurate 3-D inertial-sensor structures.

“These new fabrication methods were thought to be unrealistic just a few years ago,” said Andrei Shkel, the DARPA program manager. “The first phase of MRIG has proven these new fabrication techniques and begun the process of validating the new structures and materials through testing. Phase 2 has kicked off, in which DARPA seeks to hone these methods to create and demonstrate operational devices.”

Phase 2 performers seek to make these devices even more accurate and reliable by reducing frequency split from 10 Hz to 5 Hz, increasing decay times from 10 seconds to 100 seconds, and decreasing volume from 20 mm3 to 10 mm3. The final goal of Phase 2 is to demonstrate a working, first-of-its-kind microrate integrating gyroscope.

“As work continues, DARPA hopes these new technologies will enable large-scale production of navigation-grade microscale inertial sensors,” added Shkel. “Production of 3-D inertial sensors with these new techniques would cost about the same as today’s integrated circuit, making them orders of magnitude smaller, cheaper and more capable than current microgyroscopes.”
 
BattleJacket®
Article Link

High Impact Technology’s BattleJacket® Fuel Cell Containment System (FCCS) is a revolutionary technology designed to minimize or prevent leakage of fuel tankers due to small-arms fire, which can cause hazardous conditions for troops transporting fuel as well as operational risks caused by the resulting lack of fuel.

It has long been known that fuel itself works well as a ballistic medium — the Israelis have placed fuel tanks on the outside of their vehicles for years. As little as 12” of fuel (or liquid) will mitigate the energy of most small caliber incoming rounds. By allowing the rounds to penetrate into the fuel tankers, risk to personnel could be minimized. And a self-sealing bladder would prevent fuel loss. After all, combat aircraft have had self-sealing bladders for years, so why not ground-based tankers?

Based on this innovative thinking, HIT developed BattleJacket® self-sealing tank coating, which could be applied to tankers using an easy-to-use spray coating process.

BattleJacket® technology was developed by testing multiple elastomeric spray coating formulations for ballistic performance and selecting the best performer. The BattleJacket®(FCCS) coating is based on a specially formulated fire resistant urethane similar to the Rhino Linings USA (Rhino) spray-in bed liner modified for military applications. A special swellable super absorbent polymer was selected to be used as the basis of the self-sealing mechanism. These beads are spray encapsulated into a special layer which, when exposed to fuel, swell into a solid. This additive acts in conjunction with the urethane to tightly seal off the undesired entrance and exit holes created by a projectile.
More on link
 
How to be invisible (to radar and electromagnetic radiation):

http://www.aalto.fi/en/current/news/view/2012-10-01/

Simply invisible

01.10.2012

A metal object can be made invisible with the help of ordinary plastic, Pekka Alitalo and Constantinos Valagiannopoulos, researchers from the School of Electrical Engineering, have shown in their study.

sylinteri.jpg

The object, however, does not become invisible to the human eye – only to electromagnetic radiation at microwave frequencies. In practical terms, this means that electromagnetic waves travelling, for example, between two antennas, do not detect an object located in their path, allowing the waves to travel the distance between them despite the obstacle, without any disruption to communications.

Previously, a similar effect has only been achieved using complex devices or expensive metamaterials with a right electromagnetic response.  In contrast, the method developed by Pekka Alitalo and Constantinos Valagiannopoulos is simple and affordable.

Plastic decreases electromagnetic scattering

Pekka Alitalo explains that objects are visible because they scatter light which is electromagnetic radiation. A metal object will not, however, scatter electromagnetic radiation at microwave frequencies to the same extent when covered with a dielectric material – an insulator that does not conduct electricity. One such dielectric material is ordinary plastic used by Alitalo and Valagiannopoulos.

"Because of space limitations, often something has to be placed in front of an antenna, such as a support structure or another antenna, and the radiation transmitted by the antenna cannot then travel through the object. We were especially interested in cloaking metal objects as metal is a material that causes strong scattering and as such, greatly interferes with communications", Alitalo explains.

Preventing scattering altogether has not yet proved possible, but the plastic cover reduced scattering caused by a metal cylinder by approximately 70 per cent.

"If we want to build an 'invisibility device', it can be considered a success if over half of the scattering disappears."

Laws of physics do not prevent invisibility

So scattering from objects can be reduced at microwave frequencies, putting the objects 'out of the sight' of the waves. According to Alitalo, there is no law of physics preventing the reduction of scattering at the frequency of visible light. This would render the object invisible to the human eye.

Science has already achieved this but the object made invisible was so miniscule it was hard to detect by the human eye in any case. Alitalo explains that at the spectrum of light visible to humans, the wavelength is around a few hundred nanometres, meaning that the diameter of the object being cloaked should be even smaller than this.

There is a limit to the size of an object that can be rendered invisible even to electromagnetic radiation at microwave frequencies.

"In our study, the wavelength was ten centimetres and the diameter of the tested metal cylinder was two centimetres. When the size of the object being cloaked increases while the frequency remains the same, the method stops working at some point. If for instance a tank is covered with plastic, it does not help because the object is just too big at this specific frequency."

Text: Tea Kalska

The article "Demonstration of electromagnetic cloaking of conducting object by dielectric material cover" by Pekka Alitalo and Constantinos Valagiannopoulos was published on 16 August 2012 in the publication Electronics Letters, Vol. 48, No. 17.
 
http://www.darpa.mil/NewsEvents/Releases/2012/10/05.aspx

Making Connections At 45,000 Feet: Future UAVs May Fuel Up In Flight

DARPA completes close-proximity flight tests of two modified RQ-4 Global Hawk unmanned aerial vehicles, demonstrates technology enabling autonomous aerial refueling. 

Today DARPA has addressed this capability gap. DARPA’s two-year Autonomous High-Altitude Refueling (AHR) program, which concluded Sep. 30, explored the ability to safely conduct fully autonomous refueling of UAVs in challenging high-altitude flight conditions. During its final test flight, two modified Global Hawk aircraft flew in close formation, 100 feet or less between refueling probe and receiver drogue, for the majority of a 2.5-hour engagement at 44,800 feet. This demonstrated for the first time that High Altitude Long Endurance (HALE) class aircraft can safely and autonomously operate under in-flight refueling conditions. The flight was the ninth test and the first time the aircraft flew close enough to measure the full aerodynamic and control interactions. Flight data was analyzed over the past few months and fed back into simulations to verify system safety and performance through contact and fuel transfer–including the effects of turns and gusts up to 20 knots.



 
Carbon nanotube pencil points to hazardous gases

http://news.cnet.com/8301-17938_105-57530149-1/carbon-nanotube-pencil-points-to-hazardous-gases/

Gather 'round kiddies, and I'll tell you a story about pointy wooden things called pencils. Before the explosion of keyboards and touch screens, people used to use them to do something called writing. On paper.

Now one MIT chemistry postdoctoral student may have given the old-fashioned pencil a new lease -- though not as something you'd bring to the SAT.

Katherine Mirica and colleagues created a novel type of pencil lead, replacing graphite with a highly compressed powder made of commercially available carbon nanotubes. The resulting newfangled lead can inscribe sensors on any paper surface.

So what's the point? The sensors, described in a paper titled "Mechanical Drawing of Gas Sensors on Paper" in the German journal Angewandte Chemie, detect minute amounts of the colorless gas ammonia, an industrial hazard, but could be adapted to detect nearly any type of gas.

The MIT team, for example, is also looking into creating sensors for detecting sulfur compounds, which could prove helpful for sniffing out natural-gas leaks.

"The beauty of this is we can start doing all sorts of chemically specific functionalized materials," MIT chemistry professor Timothy Swager, leader of the research team, said in a statement. "We think we can make sensors for almost anything that's volatile."

Carbon nanotubes -- roughly 50,000 of which add up to the width of an average strand of human hair -- have been shown to be effective sensors for many gases, which bind to the nanotubes and impede electron flow. Creating sensors of this type, however, requires dissolving nanotubes in a solvent such as dichlorobenzene using a process that can be both hazardous and unreliable.
Related stories

This new fabrication method out of MIT, on the other hand, is among other advantages entirely solvent-free. To create sensors using their pencil, the researchers draw a line of carbon nanotubes on a sheet of paper imprinted with small electrodes made of gold that help measure the electrical current running through the tiny cylinders.

The research was funded by the Army Research Office through MIT's Institute for Soldier Nanotechnologies. This suggests that in addition to high expectations for carbon nanotubes in the medical realm, particularly when it comes to drug delivery and noninvasive blood monitoring, the military also sees great potential for the strong and tiny tubes.

I wonder what other gems the Institute for Soldier Nanotechnologies has waiting in the wings. Future war will not look like anything we're used to seeing.
 
More fun with nanomaterials. The idea that filling a tank with this stuff will allow you to increase the carrying capacity seems totally counter intuitive, but being able to carry more in the same volume of container will provide logistical advantages:

http://www.qub.ac.uk/home/ceao/News/Title,343081,en.html

New Queen’s spin-out company to manufacture TARDIS-like nanomaterials
Professor Stuart James
Professor Stuart James

Greatly increasing the storage capacity of gas tanks is just one of the applications being made possible because of a revolutionary TARDIS-like nanomaterial being manufactured by MOF Technologies, a new Queen’s spin-out company.

A cylinder filled with this material, known as MOFs or Metal-Organic Frameworks, can store much more gas than an empty cylinder of the same size, but until now MOF manufacturing techniques have been limited as they are costly, slow and require large quantities of solvents which can be toxic and harmful to the environment.

Now, a new technique devised by the company allows the simple, environmentally friendly production of these incredible materials, which have the potential to revolutionise applications including hazardous gas storage, natural gas vehicles, carbon capture and drug delivery.

MOFs have the highest surface-area of any known substance and a sugar-lump sized piece of MOF material can have the same surface area as a football pitch.
Professor Stuart James in Queen’s School of Chemistry and Chemical Engineering has patented a novel technique for the synthesis of MOFs, allowing affordable, large-scale deployment of these ground-breaking materials.

The new Queen’s technology is environmentally friendly, rapid and highly scalable and has resulted in the formation of MOF Technologies through Queen’s spin-out arm QUBIS. Seed funding has been provided by both QUBIS and NetScientific, which specialises in commercialising technologies developed within university laboratories.

Explaining about the vast potential for the new technique Professor James said: “The enormous internal surface-areas of MOFs allow them to soak up large amounts of gas, just like a sponge soaks up water. Once the gas is adsorbed into the material it takes up far less space than it would otherwise at the same pressure.”

CEO of MOF Technologies, Tom Robinson added: “The potential for this technology is huge. Academia has known for some time about the incredible properties of MOFs and hundreds of millions of dollars are being spent on their development, in labs around the world. We can now manufacture these materials in a scalable and environmentally-friendly way, unlocking their potential to transform the transport, gas storage and medical industries in the years to come.”

MOF Technologies is also hoping to exploit opportunities in global carbon capture, hazardous gas storage, natural gas processing and hydrocarbon separations.

Frank Bryan, interim CEO of QUBIS added “QUBIS was delighted to partner with NetScientific in the creation of our latest Queen’s University spin-out.  We exist to support acclaimed Queen’s academics, like Professor James, in commercialising their cutting edge research and we are confident this will be the latest in a long line of successes.  It was therefore particularly rewarding to see MOF Technologies win this year’s NISP Connect £25K Award which recognised the company as having the greatest potential for commercial success.”

Further information on the technology is available online at www.moftechnologies.com/ and further information on QUBIS is available online at www.qubis.co.uk/

Media inquiries to Communications Office. Tel: +44(0)28 9097 5384 or 07814 415 451 or email comms.officer@qub.ac.uk
 
More about making things on the cheap. Upthread there are several posts about using cellulose (the basic material of wood, cardboard and paper) as a super strong substitute for metals, so there are many aspects of military hardware that could be revolutionized by these technologies. Thinner, lighter and stronger packing cases, inexpensive frameworks and structural forms or even complete shelters and (of course) bikes:

http://news.nationalpost.com/2012/10/16/israeli-inventor-creates-cardboard-bicycle-that-can-change-the-world/

Israeli inventor creates cardboard bicycle that can ‘change the world’

Ori Lewis and Lianne Gross, Reuters | Oct 16, 2012 11:57 AM ET
More from Reuters
REUTERS/Baz Ratner
REUTERS/Baz Ratner Israeli inventor Izhar Gafni rides his cardboard bicycle in Moshav Ahituv, central Israel September 24, 2012.

MOSHAV AHITUV, Israel – A bicycle made almost entirely of cardboard has the potential to change transportation habits from the world’s most congested cities to the poorest reaches of Africa, its Israeli inventor says.

Izhar Gafni, 50, is an expert in designing automated mass-production lines. He is an amateur cycling enthusiast who for years toyed with an idea of making a bicycle from cardboard.

He told Reuters during a recent demonstration that after much trial and error, his latest prototype has now proven itself and mass production will begin in a few months.

“I was always fascinated by applying unconventional technologies to materials and I did this on several occasions. But this was the culmination of a few things that came together. I worked for four years to cancel out the corrugated cardboard’s weak structural points,” Gafni said.
REUTERS/Baz RatnerIsraeli inventor Izhar Gafni holds his cardboard bicycle as he poses for a photo in Moshav Ahituv, central Israel September 24, 2012.

“Making a cardboard box is easy and it can be very strong and durable, but to make a bicycle was extremely difficult and I had to find the right way to fold the cardboard in several different directions. It took a year and a half, with lots of testing and failure until I got it right,” he said.

Cardboard, made of wood pulp, was invented in the 19th century as sturdy packaging for carrying other more valuable objects, it has rarely been considered as raw material for things usually made of much stronger materials, such as metal.

Once the shape has been formed and cut, the cardboard is treated with a secret concoction made of organic materials to give it its waterproof and fireproof qualities. In the final stage, it is coated with lacquer paint for appearance.

In testing the durability of the treated cardboard, Gafni said he immersed a cross-section in a water tank for several months and it retained all its hardened characteristics.

Once ready for production, the bicycle will include no metal parts, even the brake mechanism and the wheel and pedal bearings will be made of recycled substances, although Gafni said he could not yet reveal those details due to pending patent issues.


“I’m repeatedly surprised at just how strong this material is, it is amazing. Once we are ready to go to production, the bike will have no metal parts at all,” Gafni said.

Gafni’s workshop, a ramshackle garden shed, is typically the sort of place where legendary inventions are born. It is crammed with tools and bicycle parts and cardboard is strewn everywhere.

One of his first models was a push bike he made as a toy for his young daughter which she is still using months later.

Gafni owns several top-of-the-range bicycles which he said are worth thousands of dollars each, but when his own creation reaches mass production, it should cost no more than about $20 to buy. The cost of materials used are estimated at $9 per unit.

“When we started, a year and a half or two years ago, people laughed at us, but now we are getting at least a dozen e-mails every day asking where they can buy such a bicycle, so this really makes me hopeful that we will succeed,” he said.

A ride of the prototype was quite stiff, but generally no different to other ordinary basic bikes.

Nimrod Elmish, Gafni’s business partner, said cardboard and other recycled materials could bring a major change in current production norms because grants and rebates would only be given for local production and there would be no financial benefits by making bicycles in cheap labor markets.

“This is a real game-changer. It changes … the way products are manufactured and shipped, it causes factories to be built everywhere instead of moving production to cheaper labor markets, everything that we have known in the production world can change,” he said.

Elmish said the cardboard bikes would be made on largely automated production lines and would be supplemented by a workforce comprising pensioners and the disabled.

He said that apart from the social benefits this would provide for all concerned, it would also garner government grants for the manufacturers.
Elmish said the business model they had created meant that rebates for using “green” materials would entirely cancel out production costs and this could allow for bicycles to be given away for free in poor countries.

Producers would reap financial rewards from advertisements such as from multinational companies who would pay for their logo to be part of the frame, he explained.

“Because you get a lot of government grants, it brings down the production costs to zero, so the bicycles can be given away for free. We are copying a business model from the high-tech world where software is distributed free because it includes embedded advertising,” Elmish explained.

“It could be sold for around $20, because [retailers] have to make a profit … and we think they should not cost any more than that. We will make our money from advertising,” he added.

Elmish said initial production was set to begin in Israel in months on three bicycle models and a wheelchair and they will be available to purchase within a year.

“In six months we will have completed planning the first production lines for an urban bike which will be assisted by an electric motor, a youth bike which will be a 2/3 size model for children in Africa, a balance bike for youngsters learning to ride, and a wheelchair that a non-profit organization wants to build with our technology for Africa,” he said.

The bicycles are not only very cheap to make, they are very light and do not need to be adjusted or repaired, the solid tires that are made of reconstituted rubber from old car tires will never get a puncture, Elmish said.

“These bikes need no maintenance and no adjustment, a car timing belt is used instead of a chain, and the tires do not need inflating and can last for 10 years,” he said.
REUTERS/Baz RatnerA cardboard bicycle made by Israeli inventor Izhar Gafni leans against a wall in Moshav Ahituv, central Israel September 24, 2012.

A full-size cardboard bicycle will weigh around 9 kg (about 20 lbs) compared to an average metal bicycle, which weight around 14 kg.

The urban bicycle, similar to London’s “Boris bikes” and others worldwide, will have a mounting for a personal electric motor. Commuters would buy one and use it for their journey and then take it home or to work where it could be recharged.

He said that as bicycles would be so cheap, it hardly mattered how long they lasted.

“So you buy one, use it for a year and then you can buy another one, and if it breaks, you can take it back to the factory and recycle it,” he said.

Gafni predicted that in the future, cardboard might even be used in cars and even aircraft “but that is still a way down the road.”

“We are just at the beginning and from here my vision is to see cardboard replacing metals … and countries that right now don’t have the money, will be able to benefit from so many uses for this material,” he said.
 
Back
Top