Tag Archives: US military

Graphene and smart textiles

Here’s one of the more recent efforts to create fibres that are electronic and capable of being woven into a smart textile. (Details about a previous effort can be found at the end of this post.) Now for this one, from a Dec. 3, 2018 news item on ScienceDaily,

The quest to create affordable, durable and mass-produced ‘smart textiles’ has been given fresh impetus through the use of the wonder material Graphene.

An international team of scientists, led by Professor Monica Craciun from the University of Exeter Engineering department, has pioneered a new technique to create fully electronic fibres that can be incorporated into the production of everyday clothing.

A Dec. 3, 2018 University of Exeter press release (also on EurekAlert), provides more detail about the problems associated with wearable electronics and the solution being offered (Note: A link has been removed),

Currently, wearable electronics are achieved by essentially gluing devices to fabrics, which can mean they are too rigid and susceptible to malfunctioning.

The new research instead integrates the electronic devices into the fabric of the material, by coating electronic fibres with light-weight, durable components that will allow images to be shown directly on the fabric.

The research team believe that the discovery could revolutionise the creation of wearable electronic devices for use in a range of every day applications, as well as health monitoring, such as heart rates and blood pressure, and medical diagnostics.

The international collaborative research, which includes experts from the Centre for Graphene Science at the University of Exeter, the Universities of Aveiro and Lisbon in Portugal, and CenTexBel in Belgium, is published in the scientific journal Flexible Electronics.

Professor Craciun, co-author of the research said: “For truly wearable electronic devices to be achieved, it is vital that the components are able to be incorporated within the material, and not simply added to it.

Dr Elias Torres Alonso, Research Scientist at Graphenea and former PhD student in Professor Craciun’s team at Exeter added “This new research opens up the gateway for smart textiles to play a pivotal role in so many fields in the not-too-distant future.  By weaving the graphene fibres into the fabric, we have created a new technique to all the full integration of electronics into textiles. The only limits from now are really within our own imagination.”

At just one atom thick, graphene is the thinnest substance capable of conducting electricity. It is very flexible and is one of the strongest known materials. The race has been on for scientists and engineers to adapt graphene for the use in wearable electronic devices in recent years.

This new research used existing polypropylene fibres – typically used in a host of commercial applications in the textile industry – to attach the new, graphene-based electronic fibres to create touch-sensor and light-emitting devices.

The new technique means that the fabrics can incorporate truly wearable displays without the need for electrodes, wires of additional materials.

Professor Saverio Russo, co-author and from the University of Exeter Physics department, added: “The incorporation of electronic devices on fabrics is something that scientists have tried to produce for a number of years, and is a truly game-changing advancement for modern technology.”

Dr Ana Neves, co-author and also from Exeter’s Engineering department added “The key to this new technique is that the textile fibres are flexible, comfortable and light, while being durable enough to cope with the demands of modern life.”

In 2015, an international team of scientists, including Professor Craciun, Professor Russo and Dr Ana Neves from the University of Exeter, have pioneered a new technique to embed transparent, flexible graphene electrodes into fibres commonly associated with the textile industry.

Here’s a link to and a citation for the paper,

Graphene electronic fibres with touch-sensing and light-emitting functionalities for smart textiles by Elias Torres Alonso, Daniela P. Rodrigues, Mukond Khetani, Dong-Wook Shin, Adolfo De Sanctis, Hugo Joulie, Isabel de Schrijver, Anna Baldycheva, Helena Alves, Ana I. S. Neves, Saverio Russo & Monica F. Craciun. Flexible Electronicsvolume 2, Article number: 25 (2018) DOI: https://doi.org/10.1038/s41528-018-0040-2 Published 25 September 2018

This paper is open access.

I have an earlier post about an effort to weave electronics into textiles for soldiers, from an April 5, 2012 posting,

I gather that today’s soldier (aka, warfighter)  is carrying as many batteries as weapons. Apparently, the average soldier carries a couple of kilos worth of batteries and cables to keep their various pieces of equipment operational. The UK’s Centre for Defence Enterprise (part of the Ministry of Defence) has announced that this situation is about to change as a consequence of a recently funded research project with a company called Intelligent Textiles. From Bob Yirka’s April 3, 2012 news item for physorg.com,

To get rid of the cables, a company called Intelligent Textiles has come up with a type of yarn that can conduct electricity, which can be woven directly into the fabric of the uniform. And because they allow the uniform itself to become one large conductive unit, the need for multiple batteries can be eliminated as well.

I dug down to find more information about this UK initiative and the Intelligent Textiles company but the trail seems to end in 2015. Still, I did find a Canadian connection (for those who don’t know I’m a Canuck) and more about Intelligent Textile’s work with the British military in this Sept. 21, 2015 article by Barry Collins for alphr.com (Note: Links have been removed),

A two-person firm operating from a small workshop in Staines-upon-Thames, Intelligent Textiles has recently landed a multimillion-pound deal with the US Department of Defense, and is working with the Ministry of Defence (MoD) to bring its potentially life-saving technology to British soldiers. Not bad for a company that only a few years ago was selling novelty cushions.

Intelligent Textiles was born in 2002, almost by accident. Asha Peta Thompson, an arts student at Central Saint Martins, had been using textiles to teach children with special needs. That work led to a research grant from Brunel University, where she was part of a team tasked with creating a “talking jacket” for the disabled. The garment was designed to help cerebral palsy sufferers to communicate, by pressing a button on the jacket to say “my name is Peter”, for example, instead of having a Stephen Hawking-like communicator in front of them.

Another member of that Brunel team was engineering lecturer Dr Stan Swallow, who was providing the electronics expertise for the project. Pretty soon, the pair realised the prototype waistcoat they were working on wasn’t going to work: it was cumbersome, stuffed with wires, and difficult to manufacture. “That’s when we had the idea that we could weave tiny mechanical switches into the surface of the fabric,” said Thompson.

The conductive weave had several advantages over packing electronics into garments. “It reduces the amount of cables,” said Thompson. “It can be worn and it’s also washable, so it’s more durable. It doesn’t break; it can be worn next to the skin; it’s soft. It has all the qualities of a piece of fabric, so it’s a way of repackaging the electronics in a way that’s more user-friendly and more comfortable.” The key to Intelligent Textiles’ product isn’t so much the nature of the raw materials used, but the way they’re woven together. “All our patents are in how we weave the fabric,” Thompson explained. “We weave two conductive yarns to make a tiny mechanical switch that is perfectly separated or perfectly connected. We can weave an electronic circuit board into the fabric itself.”

Intelligent Textiles’ big break into the military market came when they met a British textiles firm that was supplying camouflage gear to the Canadian armed forces. [emphasis mine] The firm was attending an exhibition in Canada and invited the Intelligent Textiles duo to join them. “We showed a heated glove and an iPod controller,” said Thompson. “The Canadians said ‘that’s really fantastic, but all we need is power. Do you think you could weave a piece of fabric that distributes power?’ We said, ‘we’re already doing it’.”Before long it wasn’t only power that the Canadians wanted transmitted through the fabric, but data.

“The problem a soldier faces at the moment is that he’s carrying 60 AA batteries [to power all the equipment he carries],” said Thompson. “He doesn’t know what state of charge those batteries are at, and they’re incredibly heavy. He also has wires and cables running around the system. He has snag hazards – when he’s going into a firefight, he can get caught on door handles and branches, so cables are a real no-no.”

The Canadians invited the pair to speak at a NATO conference, where they were approached by military brass with more familiar accents. “It was there that we were spotted by the British MoD, who said ‘wow, this is a British technology but you’re being funded by Canada’,” said Thompson. That led to £235,000 of funding from the Centre for Defence Enterprise (CDE) – the money they needed to develop a fabric wiring system that runs all the way through the soldier’s vest, helmet and backpack.

There are more details about the 2015 state of affairs, textiles-wise, in a March 11, 2015 article by Richard Trenholm for CNET.com (Note: A link has been removed),

Speaking at the Wearable Technology Show here, Swallow describes IT [Intelligent Textiles]L as a textile company that “pretends to be a military company…it’s funny how you slip into these domains.”

One domain where this high-tech fabric has seen frontline action is in the Canadian military’s IAV Stryker armoured personnel carrier. ITL developed a full QWERTY keyboard in a single piece of fabric for use in the Stryker, replacing a traditional hardware keyboard that involved 100 components. Multiple components allow for repair, but ITL knits in redundancy so the fabric can “degrade gracefully”. The keyboard works the same as the traditional hardware, with the bonus that it’s less likely to fall on a soldier’s head, and with just one glaring downside: troops can no longer use it as a step for getting in and out of the vehicle.

An armoured car with knitted controls is one thing, but where the technology comes into its own is when used about the person. ITL has worked on vests like the JTAC, a system “for the guys who call down airstrikes” and need “extra computing oomph.” Then there’s SWIPES, a part of the US military’s Nett Warrior system — which uses a chest-mounted Samsung Galaxy Note 2 smartphone — and British military company BAE’s Broadsword system.

ITL is currently working on Spirit, a “truly wearable system” for the US Army and United States Marine Corps. It’s designed to be modular, scalable, intuitive and invisible.

While this isn’t an ITL product, this video about Broadsword technology from BAE does give you some idea of what wearable technology for soldiers is like,

baesystemsinc

Uploaded on Jul 8, 2014

Broadsword™ delivers groundbreaking technology to the 21st Century warfighter through interconnecting components that inductively transfer power and data via The Spine™, a revolutionary e-textile that can be inserted into any garment. This next-generation soldier system offers enhanced situational awareness when used with the BAE Systems’ Q-Warrior® see-through display.

If anyone should have the latest news about Intelligent Textile’s efforts, please do share in the comments section.

I do have one other posting about textiles and the military, which is dated May 9, 2012, but while it does reference US efforts it is not directly related to weaving electronics into solder’s (warfighter’s) gear.

You can find CenTexBel (Belgian Textile Rsearch Centre) here and Graphenea here. Both are mentioned in the University of Exeter press release.

Nanotechnology and cybersecurity risks

Gregory Carpenter has written a gripping (albeit somewhat exaggerated) piece for Signal, a publication of the  Armed Forces Communications and Electronics Association (AFCEA) about cybersecurity issues and  nanomedicine endeavours. From Carpenter’s Jan. 1, 2016 article titled, When Lifesaving Technology Can Kill; The Cyber Edge,

The exciting advent of nanotechnology that has inspired disruptive and lifesaving medical advances is plagued by cybersecurity issues that could result in the deaths of people that these very same breakthroughs seek to heal. Unfortunately, nanorobotic technology has suffered from the same security oversights that afflict most other research and development programs.

Nanorobots, or small machines [or nanobots[, are vulnerable to exploitation just like other devices.

At the moment, the issue of cybersecurity exploitation is secondary to making nanobots, or nanorobots, dependably functional. As far as I’m aware, there is no such nanobot. Even nanoparticles meant to function as packages for drug delivery have not been perfected (see one of the controversies with nanomedicine drug delivery described in my Nov. 26, 2015 posting).

That said, Carpenter’s point about cybersecurity is well taken since security features are often overlooked in new technology. For example, automated banking machines (ABMs) had woefully poor (inadequate, almost nonexistent) security when they were first introduced.

Carpenter outlines some of the problems that could occur, assuming some of the latest research could be reliably  brought to market,

The U.S. military has joined the fray of nanorobotic experimentation, embarking on revolutionary research that could lead to a range of discoveries, from unraveling the secrets of how brains function to figuring out how to permanently purge bad memories. Academia is making amazing advances as well. Harnessing progress by Harvard scientists to move nanorobots within humans, researchers at the University of Montreal, Polytechnique Montreal and Centre Hospitalier Universitaire Sainte-Justine are using mobile nanoparticles inside the human brain to open the blood-brain barrier, which protects the brain from toxins found in the circulatory system.

A different type of technology presents a risk similar to the nanoparticles scenario. A DARPA-funded program known as Restoring Active Memory (RAM) addresses post-traumatic stress disorder, attempting to overcome memory deficits by developing neuroprosthetics that bridge gaps in an injured brain. In short, scientists can wipe out a traumatic memory, and they hope to insert a new one—one the person has never actually experienced. Someone could relish the memory of a stroll along the French Riviera rather than a terrible firefight, even if he or she has never visited Europe.

As an individual receives a disruptive memory, a cyber criminal could manage to hack the controls. Breaches of the brain could become a reality, putting humans at risk of becoming zombie hosts [emphasis mine] for future virus deployments. …

At this point, the ‘zombie’ scenario Carpenter suggests seems a bit over-the-top but it does hearken to the roots of the zombie myth where the undead aren’t mindlessly searching for brains but are humans whose wills have been overcome. Mike Mariani in an Oct. 28, 2015 article for The Atlantic has presented a thought-provoking history of zombies,

… the zombie myth is far older and more rooted in history than the blinkered arc of American pop culture suggests. It first appeared in Haiti in the 17th and 18th centuries, when the country was known as Saint-Domingue and ruled by France, which hauled in African slaves to work on sugar plantations. Slavery in Saint-Domingue under the French was extremely brutal: Half of the slaves brought in from Africa were worked to death within a few years, which only led to the capture and import of more. In the hundreds of years since, the zombie myth has been widely appropriated by American pop culture in a way that whitewashes its origins—and turns the undead into a platform for escapist fantasy.

The original brains-eating fiend was a slave not to the flesh of others but to his own. The zombie archetype, as it appeared in Haiti and mirrored the inhumanity that existed there from 1625 to around 1800, was a projection of the African slaves’ relentless misery and subjugation. Haitian slaves believed that dying would release them back to lan guinée, literally Guinea, or Africa in general, a kind of afterlife where they could be free. Though suicide was common among slaves, those who took their own lives wouldn’t be allowed to return to lan guinée. Instead, they’d be condemned to skulk the Hispaniola plantations for eternity, an undead slave at once denied their own bodies and yet trapped inside them—a soulless zombie.

I recommend reading Mariani’s article although I do have one nit to pick. I can’t find a reference to brain-eating zombies until George Romero’s introduction of the concept in his movies. This Zombie Wikipedia entry seems to be in agreement with my understanding (if I’m wrong, please do let me know and, if possible, provide a link to the corrective text).

Getting back to Carpenter and cybersecurity with regard to nanomedicine, while his scenarios may seem a trifle extreme it’s precisely the kind of thinking you need when attempting to anticipate problems. I do wish he’d made clear that the technology still has a ways to go.

Petman and lifelike movement

Thanks to the Nov. 7, 2011 posting on the Foresight Institute blog, I’ve found Petman,

Last month we noted the impressive progress achieved by Boston Dynamics’ AlphaDog project to develop a robot “pack animal” for the US military. Apparently there has been equally impressive progress in developing a humanoid robot capable of faithfully mimicking human movements to test protective suits for use by the military, and ultimately, to replace humans in a variety of arduous and dangerous tasks. This month IEEE Spectrum gave us this update: “Stunning Video of PETMAN Humanoid Robot From Boston Dynamics”, by Erico Guizzo.

I have written about Boston Dynamics and its military robots before, most recently about Big Dog in my Feb. 2, 2010 posting [scroll down a paragraph or two]. It’s amazing to see how much smoother the movement has become although I notice that the robot is tethered. From the Oct. 31, 2011 IEEE Spectrum article by Erico Guizzo,

It can walk, squat, kneel, and even do push-ups.

PETMAN is an adult-sized humanoid robot developed by Boston Dynamics, the robotics firm best known for the BigDog quadruped.

Today, the company is unveiling footage of the robot’s latest capabilities. It’s stunning.

The humanoid, which will certainly be compared to the Terminator Series 800 model, can perform various movements and maintain its balance much like a real person.

Boston Dynamics is building PETMAN, short for Protection Ensemble Test Mannequin, for the U.S. Army, which plans to use the robot to test chemical suits and other protective gear used by troops. It has to be capable of moving just like a soldier — walking, running, bending, reaching, army crawling — to test the suit’s durability in a full range of motion.

Marc Raibert, the founder and president of Boston Dynamics, tells me that the biggest challenge was to engineer the robot, which uses a hydraulic actuation system, to have the approximate size of a person. “There was a great deal of mechanical design we had to do to get everything to fit,” he says.

The Guizzo article features a number of images and a video demonstrating Petman’s abilities along with more details about the robot’s full capabilities. I went on YouTube to find this Petman mashup,

The Japanese have featured some robots that look like and dance like people as I noted in my Oct. 18, 2010 posting where I also discussed the ‘uncanny valley’ in relationship to those robots. Keeping on the ‘humanoid’ robot theme, I also posted about Geminoid robots in the context of a Danish philosopher who commissioned, for a philosophy project, a Geminoid that looked like himself and whose facial features are expressive. In that same posting, March 10, 2011, I wrote about some work at the Georgia Institute of Technology (US) where they too are developing robots that move like humans. The March 2011 posting features more information about the ‘uncanny valley’, including a diagram.

I wonder what it will be like to encounter one of these humanoid robots in the flesh as it were.