Now, impact sensor to generate electricity, reveal impact forces for athletes

May 15, 2010 By Leave a Comment

Washington, May 15 (ANI): A new type of wearable impact sensor, developed by New Zealand researchers, could soon provide much needed information about the stresses and strains on limbs for rugby players, high jumpers, and runners.

The new sensor could help athletes striving for perfection.

Kean Aw and colleagues in the department of Mechanical Engineering, at The University of Auckland, explain how novel materials known as ionic polymer metallic composites (IPMCs), produce an electrical current when compressed.

These materials are flexible, lightweight and durable and so can be fashioned into wearable sensor devices to allow sports scientists to monitor directly impact forces without interfering with an athlete”s performance.

IPMCs are usually made from an ionic polymer, such as Nafion or Flemion, which is coated with a conducting metal, platinum or gold.

Earlier, researchers have experimented with IPMC materials as artificial muscles because applying a voltage causes them to flex as ions migrate causing electrostatic repulsion within the composite material.

The opposite effect, in which ion movement generated a voltage when the material is flexed, is exploited in the sensor technology.

Impact sensors made from IPMC could be inserted into footwear to measure the impact energy of a foot striking a hard surface or they might be placed in a rugby player”s shoulder pads to measure collision impacts or forces exerted during a rugby scrum.

The data obtained from these sensors allows the athlete”s performance to be quantified and analysed in terms of the forces acting on their body with a view to improving their stamina and also reducing the potential for injuries.

The researchers have tested IPMC sensors in the laboratory and compared the readings obtained for different applied forces with those from more conventional measurement techniques.

Their analysis of the tests reveals that the IPMC sensors would have to be calibrated with a high and a low impact force prior to testing with a performing athlete.

However, the voltage spike and the slope of the voltage measurement obtained with an IPMC can be readily converted into an impact force measurement to within 10 percent accuracy.

The study has been published in the International Journal of Biomechatronics and Biomedical Robotics. (ANI)

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Jelly thickener may help grow artificial muscles in future

July 14, 2009 By Leave a Comment

Melbourne, July 14 (ANI): In a novel study, Australian researchers are using food thickener used in yoghurts and jellies to develop artificial muscle.

Nanotechnology graduate Cameron Ferris, and supervisor Dr. Marc in het Panhuis, of the University of Wollongong, have developed a scaffold with the help of gellan gum-a biopolymer produced by the bacteria Pseudomonas elodea-that can help get cells to grow into the right kind of tissue.

“At home it’s used as a food additive. You’ll find it in lots of yoghurts and jellies as a thickener and emulsifier,” ABC Online quoted Ferris as saying.

Gellan gum is particularly useful because it becomes a gel at 37 degree Celsius, which is a good temperature for living cells, he adds.

Using the novel scaffold, the researchers are trying to develop artificial heart muscle that may soon be used to replace damaged parts of the heart in heart attacks patients.

“Muscle and heart need electrical stimulation for the cells to achieve their fully differentiated functioning state,” said Ferris.

To achieve this, Ferris has made a scaffold that mixes the gellan gum with carbon nanotubes, which conduct electricity.

To date, Ferris has successfully grown fibroblasts on his gellan gum and carbon nanotube scaffold but has “steered away” from using carbon nanotubes because of “unanswered questions” over their safety.

“Some (studies) say they’re fine and that they can be passed out of the body when the scaffold degrades,” he said.

“Others have said that they’re quite toxic to cells or can accumulate in the lungs,” he added.

The study has been published in the journal Soft Matter. (ANI)

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Jelly thickener may help grow artificial muscles in future

July 14, 2009 By Leave a Comment

Melbourne, July 14 (ANI): In a novel study, Australian researchers are using food thickener used in yoghurts and jellies to develop artificial muscle.

Nanotechnology graduate Cameron Ferris, and supervisor Dr. Marc in het Panhuis, of the University of Wollongong, have developed a scaffold with the help of gellan gum-a biopolymer produced by the bacteria Pseudomonas elodea-that can help get cells to grow into the right kind of tissue.

“At home it’s used as a food additive. You’ll find it in lots of yoghurts and jellies as a thickener and emulsifier,” ABC Online quoted Ferris as saying.

Gellan gum is particularly useful because it becomes a gel at 37 degree Celsius, which is a good temperature for living cells, he adds.

Using the novel scaffold, the researchers are trying to develop artificial heart muscle that may soon be used to replace damaged parts of the heart in heart attacks patients.

“Muscle and heart need electrical stimulation for the cells to achieve their fully differentiated functioning state,” said Ferris.

To achieve this, Ferris has made a scaffold that mixes the gellan gum with carbon nanotubes, which conduct electricity.

To date, Ferris has successfully grown fibroblasts on his gellan gum and carbon nanotube scaffold but has “steered away” from using carbon nanotubes because of “unanswered questions” over their safety.

“Some (studies) say they’re fine and that they can be passed out of the body when the scaffold degrades,” he said.

“Others have said that they’re quite toxic to cells or can accumulate in the lungs,” he added.

The study has been published in the journal Soft Matter. (ANI)

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Robot taught to smile and frown through self-guided learning

July 10, 2009 By Leave a Comment

Washington, July 9 (ANI): Scientists at the University of California, San Diego, have revealed that a hyper-realistic Einstein robot has learnt to smile and make facial expressions through a process of self-guided learning.

The researchers say that they took the aid of machine learning to “empower” their robot to learn to make realistic facial expressions.

“As far as we know, no other research group has used machine learning to teach a robot to make realistic facial expressions,” said Tingfan Wu, the computer science Ph.D. student from the UC San Diego Jacobs School of Engineering who presented this advance on June 6 at the IEEE International Conference on Development and Learning.

The researchers have even uploaded a video showing the Einstein robot head performing asymmetric random facial movements as a part of the expression learning process on the website YouTube.

The faces of robots are increasingly realistic, and the number of artificial muscles that controls them is rising.

It was in light of this trend that the researchers from the Machine Perception Laboratory are studying the face and head of their robotic Einstein, hoping that their work may help them find ways to automate the process of teaching robots to make lifelike facial expressions.

According to them, the Einstein robot they worked on has about 30 facial muscles, each moved by a tiny servo motor connected to the muscle by a string.

The researchers point out that developmental psychologists speculate that infants learn to control their bodies through systematic exploratory movements, including babbling to learn to speak.

Initially, these movements appear to be executed in a random manner as infants learn to control their bodies and reach for objects.

“We applied this same idea to the problem of a robot learning to make realistic facial expressions,” said Javier Movellan, the senior author on the paper presented at ICDL 2009 and the director of UCSD’s Machine Perception Laboratory, housed in Calit2, the California Institute for Telecommunications and Information Technology.

The research team may have achieved promising results, but they admit that some of the learned facial expressions are still awkward. One potential explanation is that their model may be too simple to describe the coupled interactions between facial muscles and skin.

To begin the learning process, the UC San Diego researchers directed the Einstein robot head to twist and turn its face in all directions, a process called “body babbling”.

During that period, the robot could see itself on a mirror and analyse its own expression using facial expression detection software created at UC San Diego called CERT (Computer Expression Recognition Toolbox).

That provided the data necessary for machine learning algorithms to learn a mapping between facial expressions and the movements of the muscle motors.

After the robot had learnt the relationship between facial expressions and the muscle movements required to make them, the researchers made it learn to make facial expressions it had never encountered.

For example, the robot learned eyebrow narrowing, which requires the inner eyebrows to move together and the upper eyelids to close a bit to narrow the eye aperture.

“During the experiment, one of the servos burned out due to misconfiguration. We therefore ran the experiment without that servo. We discovered that the model learned to automatically compensate for the missing servo by activating a combination of nearby servos,” the authors wrote in the paper presented at the 2009 IEEE International Conference on Development and Learning.

“Currently, we are working on a more accurate facial expression generation model as well as systematic way to explore the model space efficiently,” said Wu, the computer science PhD student.

Wu concedes that his team’s “body babbling” approach may not be the most efficient way to explore the model of the face.

While the primary goal of this work was to solve the engineering problem of how to approximate the appearance of human facial muscle movements with motors, the researchers say this kind of work could also lead to insights into how humans learn and develop facial expressions. (ANI)

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Soon, robots could have muscles stronger than steel

March 20, 2009 By Leave a Comment

London, March 20 (ANI): Scientists have created a new material that is stronger than steel and stiffer than diamond, weighs little more than its volume in air, and could be the perfect artificial muscle for robots.

According to a report in New Scientist, scientists at the University of Texas, Dallas, US, developed the material.

“We’ve made a totally new type of artificial muscle that is able to provide performance characteristics that have not previously been obtained,” said Ray Baughman, a materials scientist at the University of Texas, and co-developer of the new muscle.

Baughman and colleagues have developed a technique to make ribbons of tangled nanotubes that expand in width by 220 percent when a voltage is applied and then return to their normal size once it is removed.

The process takes only milliseconds.

“Collections of those ribbons could act as artificial muscle fibres – for example, to move the limbs of a walking robot,” said Baughman.

The material has other impressive properties.

It is extremely stiff and strong in the “long” direction – that in which the nanotubes are aligned – but is as stretchy as rubber across its width.

It also maintains its properties over an extreme range of temperatures: from -196 degrees Celsius, at which temperature nitrogen is liquid, to 1538 degrees C, above the melting point of iron.

This means any robot equipped with the nanotube muscles could potentially keep working in some very extreme environments.

The new material has some advantages over previous artificial muscles.

Some of those work only when bathed in methanol fuel, others are capable of only very small changes in size and none of them work well at extreme temperatures.

The tangled nanotubes are constructed into a film that can be described as an aerogel, meaning it contains more air than anything else.

Ribbons of the aerogel are made by first growing “forests” of carbon nanotubes that resemble a dense thicket of bamboo stalks.

The researchers then stick a length of adhesive to the sides of those stalks and pull gently to draw out a long, thin film of the tubes, which tangle during the process.

So far, ribbons a 50th of a millimeter thick by 16 centimeters wide and several meters long have been made, but it should be possible to form larger sheets by starting with more nanotubes.

According to Electrical engineer John Madden at the University of British Columbia, resilience and low density could make it a good material for building structures in space, with its lightness keeping down the cost of sending a payload into orbit. (ANI)

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Now, artificial muscles to restore wink and smile

March 12, 2009 By Leave a Comment

Washington, Mar 12 (ANI): People who lose control over their facial muscles have now got a new lease of life, for scientists have now developed a technique that could restore their ability to wink, and eventually may help them smile by implanting an artificial muscle in their temple.

Developed at the University of California, Davis and SRI International, the technique has shown promising results on cadavers.

The researchers say that the novel technique may eventually help living people suffering from stroke, Mobius Syndrome, or battlefield injuries gain control over the muscles in their face.

“The concept is very exciting; thousands of people could benefit from this. Theoretically it could have a wide range of applications if it turns out to be useful,” Discovery News quoted Wayne Larabee, a surgeon and editor of the Archives of Facial Plastic and Reconstructive Surgery, as saying.

One can lose the ability to control facial muscles in many ways-while those with Mobius Syndrome, are born without the ability to make facial expressions, others have facial tumours removed, and lose the nerve that extends out of the brain near the ear and spreads out on the face.

One of the most common and aesthetically pleasing options to restore a wink is to embed a small 1.2-gram, chip of gold in the eyebrow. The weight of the gold works to pull the eye closed, rather than relying on muscle.

Other surgical options include transplanting an entire section of muscle, nerve, artery and vein and sewing it to the face or co-opting the jaw muscle to pull the eye closed. Both give faster control but look unnatural and have safety risks.

“Our goal was to find a way to reanimate the face while minimizing the risk to patients,” said Travis Tollefson, a surgeon at UC-Davis, who along with Craig Senders, have successfully tried the technique in human cadavers and gerbils.

For their study, the researchers began with the same incisions that would implant a gold chip into the upper eyelid, but instead of gold, they implanted a “sling” of Gore-Tex, the same waterproof and breathable fabric commonly found in outdoor pants and jackets.

Then the surgeons placed another sling at the lower eye by using the same incision for a lower eyelid reduction. Both slings are anchored by the nose, and attached to an artificial muscle hidden in the temple.

The artificial muscle used for the technique was three-layered and consisted of a soft acrylic or silicon centre sandwiched between two layers of charged, FDA-approved black silicon.

When an electric current passes through the silicon it draws the two outer layers together, squishing the soft inner layer into four to five times its original size. This draws the sling back and closes the eye.

A similar set up could be used to draw up the corners of the mouth into a smile. (ANI)

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