Archive for the ‘robots’ Category

« Older Entries

Harvard University researcher Chirarattananom’s Flight of the RoboBee

Friday, May 3rd, 2013

The flight of  Chirarattananom’s RoboBee took place last summer but the research has only now been published. There’s a May 2, 2013 news release on EurekAlert heralding this robotic first from 2012,

In the very early hours of the morning, in a Harvard robotics laboratory last summer, an insect took flight. Half the size of a paperclip, weighing less than a tenth of a gram, it leapt a few inches, hovered for a moment on fragile, flapping wings, and then sped along a preset route through the air.

Like a proud parent watching a child take its first steps, graduate student Pakpong Chirarattananon immediately captured a video of the fledgling and emailed it to his adviser and colleagues at 3 a.m.—subject line, “Flight of the RoboBee.”

“I was so excited, I couldn’t sleep,” recalls Chirarattananon, co-lead author of a paper published this week in Science.

The demonstration of the first controlled flight of an insect-sized robot is the culmination of more than a decade’s work, led by researchers at the Harvard School of Engineering and Applied Sciences (SEAS) and the Wyss Institute for Biologically Inspired Engineering at Harvard.

Here’s what it looks like,

The tiny robot flaps its wings 120 times per second using piezoelectric actuators -- strips of ceramic that expand and contract when an electric field is applied. Thin hinges of plastic embedded within the carbon fiber body frame serve as joints, and a delicately balanced control system commands the rotational motions in the flapping-wing robot, with each wing controlled independently in real-time. Credit: Kevin Ma and Pakpong Chirarattananon, Harvard University.

The tiny robot flaps its wings 120 times per second using piezoelectric actuators — strips of ceramic that expand and contract when an electric field is applied. Thin hinges of plastic embedded within the carbon fiber body frame serve as joints, and a delicately balanced control system commands the rotational motions in the flapping-wing robot, with each wing controlled independently in real-time.
Credit: Kevin Ma and Pakpong Chirarattananon, Harvard University.

The Harvard [University] Gazette May 2, 2013 article by Caroline Perry, which originated the news release, provides more detail about what makes this particular robotic work unique,

“We had to develop solutions from scratch, for everything,” explains Wood [Robert J. Wood, Charles River Professor of Engineering and Applied Sciences at SEAS, Wyss core faculty member, and principal investigator of the National Science Foundation-supported RoboBee project]. “We would get one component working, but when we moved onto the next, five new problems would arise. It was a moving target.”

Flight muscles, for instance, don’t come prepackaged for robots the size of a fingertip.

“Large robots can run on electromagnetic motors, but at this small scale you have to come up with an alternative, and there wasn’t one,” says co-lead author Kevin Y. Ma, a graduate student at SEAS.

The tiny robot flaps its wings with piezoelectric actuators — strips of ceramic that expand and contract when an electric field is applied. Thin hinges of plastic embedded within the carbon fiber body frame serve as joints, and a delicately balanced control system commands the rotational motions in the flapping-wing robot, with each wing controlled independently in real time.

At tiny scales, small changes in airflow can have an outsized effect on flight dynamics, and the control system has to react that much faster to remain stable.

While it’s called the RoboBee project, the researchers’ inspiration for this prototype is a fly. Unlike most flies, this one is tethered, at least for now (from Perry’s article),

The prototypes are still tethered by a very thin power cable because there are no off-the-shelf solutions for energy storage that are small enough to be mounted on the robot’s body. High-energy-density fuel cells must be developed before the RoboBees will be able to fly with much independence.

Future research plans include (from Perry’s article),

… integrating the parallel work of many different research teams that are working on the brain, the colony coordination behavior, the power source, and so on, until the robotic insects are fully autonomous and wireless.

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

Controlled Flight of a Biologically Inspired, Insect-Scale Robot by Kevin Y. Ma,  Pakpong Chirarattananon,  Sawyer B. Fuller, and Robert J. Wood. Science 3 May 2013: Vol. 340 no. 6132 pp. 603-607 DOI: 10.1126/science.1231806

The paper is behind a paywall.

On reading about the RoboBee project I was reminded of Michael Crichton’s 2002 cautionary tale, Prey, which focuses on a possible future where small, swarming bots that fly threaten to take over the world. More happily, I was also inspired musically and found this rendition of the Flight of the Bumblebee,

Have a nice Friday, May 3, 2013!

Tags: , , , , , , , , , , , , , , ,
Posted in biomimcry, nanotechnology, robots | No Comments »

Home is the robot, home from the sea

Wednesday, March 27th, 2013

A Mar. 26, 2013 news item on Nanowerk features a robotics project designed for inspecting cargo vessels (Note: A link has been remvoed),

For huge cargo vessels that carry millions of litres of oil, thousands of shipping containers, or tens of thousands of tonnes of coal or steel, safety is paramount. These ships must comply with rising safety standards that require time-consuming inspections by surveyors, who in turn risk their own safety by climbing inside massive cargo areas and on scaffolding constructed around ships.

To help save time and money, and improve the accuracy and quality of these important inspections, an EU-funded research project has developed a fleet of remote-controlled robots that crawl through cargo ships in search of cracks, corrosion and other defects.

Equipped with robotic arms, cameras and magnetic wheels, the robots roll up and down the high, steep walls of ships, looking for defects on the massive steel plates and measuring their thickness with ultrasound. Controlled from a central station using virtual reality techniques, the robots crawl throughout the ship – taking pictures, videos and measurements without the need for human inspectors to go inside the hold or climb up scaffolding.

The project , known as MINOAS (Marine INspection rObotic Assistant System), holds the potential to make ships safer while also extending their life at sea.

The European Commission website (http://ec.europa.eu/research/transport/projects/items/minoas-maintenance-robots_en.htm) features this explanatory video,

Here’s more from the European Commission ‘MINOAS news’ page,

Among the four models of MINOAS robots is the “Magnet Crawler”, a two-wheeled, battery-powered device with a miniature video camera, two motors and a handle-shaped elastic tail. Weighing less than a kilogram, it climbs walls at a half-metre per second and transmits videos and images to human inspectors carrying hand-held receivers.

In a demonstration of their teamwork, the robots can conduct inspections in pairs – the first using a brush to clear away rust and dirt so that the second robot can use its ultrasonic device to measure the thickness of the wall. The robots’ advanced locomotion abilities enable them to operate in every compartment of ships.

The robots offer other advantages over human inspectors. “With the robots, we expect to obtain more data – quicker,” said Grasso [Alessandro Grasso of the Italian classification society RINA], whose organisation is charged with, among other responsibilities, certifying the safety and environmental worthiness of ships. “By having more detailed data, we can make more accurate comparisons with previous inspections, to see if there have been any changes that need to be addressed.”

This last point carries extra importance. By closely monitoring cracks, weak spots and other types of deterioration over time, ship owners will better be able to estimate future damage and the costs to repair it.

Grasso said MINOAS has received great interest at technology expos, and the project team expects the robots to reach the commercial market in the foreseeable future.

There is also a MINOAS website here.

For interested parties, the headline is a paraphrase of a line from a Robert Louis Stevenson poem. Interestingly, the original line is often misquoted according to the Wikipedia essay on Stevenson,

Stevenson had always wanted his ‘Requiem’ inscribed on his tomb:

Under the wide and starry sky,
Dig the grave and let me lie.
Glad did I live and gladly die,
And I laid me down with a will.
This be the verse you grave for me:
Here he lies where he longed to be;
Home is the sailor, home from sea,
And the hunter home from the hill.

However, the piece is misquoted in many places, including his tomb:

Home is the sailor, home from the sea,
And the hunter home from the hill.

Tags: , , , ,
Posted in robots | No Comments »

Shake hands with Sacha, a robot controlled by carbon nanotube transistors

Monday, March 18th, 2013

Since we use computer chips built from silicon in any number devices including robots, the announcement of a robot controlled by the first computer chip built entirely of a material other silicon bears notice. From the Mar. 15, 2013 news item on Nanowerk (Note: Links have been removed),

A group of Stanford researchers recently debuted the first robot controlled by a computer chip built entirely from carbon nanotube transistors, which many scientists predict may eventually replace silicon.

While scientists have produced simple demonstrations of working carbon nanotube circuit components in the past, the Stanford team, led by Professor of Electrical Engineering Philip Wong and Associate Professor of Electrical Engineering and Computer Science Subhasish Mitra Ph.D. ’00, was able to demonstrate an actual subsystem composed entirely of the material.

The news item was originated by a Mar. 7, 2013 article by Nikhita Obeegadoo for the Stanford Daily, where she noted,

The project was presented in the form of a robot named Sacha at the 2013 International Solid-State Circuits Conference (“Sacha, the Stanford Carbon Nanotube Controlled Handshaking Robot”), which was held in San Francisco. According to Mitra, the robot was created to demonstrate the development of a system that can function despite the errors caused by inherently imperfect nanotubes, which have posed issues for research teams working with carbon nanotubes in the past.

“Through several generations of technology, devices keep getting smaller and denser, and silicon will no longer be the best material for the purpose in about ten years,” Guha [Supratik Guha, director of physical sciences at IBM’s Yorktown Heights Research Center] said. “For needs that are close to atomic dimensions, carbon nanotubes have just the right shape and the right electrical behavior.”

Eric Juma on his eponymous blog offers more insight into the project in his Mar. 16, 2013 posting,

… The robot contained a carbon nanotube capacitor, a device found in many touchscreens, connected to another nanotube circuit, which turned the analog signal from the capacitor into a digital signal, which was transmitted to the microprocessor that contained CNT transistors. The microporcessor then sent a signal to a motor on the hand of the robot, which shook the person’s hand that touched the capacitors embedded in it.

This is not the first example of carbon nanotube circuitry, but it is the first example of CNTs being produced at mass for a microprocessor and circuit that were integrated. This advancement showed that it is possible to produce mass amounts of CNTs and have them integrate succesfully into a complex system. Although the size of the CNTs in this system are far from the optimal size of 10nm, it is a good starting point, and the nanotubes still can be much further refined.

Carbon nanotubes, although perfect in theory for microprocessors, present new challenges for engineers. The greatest challenge is the actual integration of CNTs into circuitry. Nanotubes often force themselves into a tangled position, which can cause circuits to fail without warning.

Juma gives a good explanation for why there is so much interest in carbon nanotubes in the field of electronics and he provides links to more information about it all. (There’s a video about carbon nanotubes and their various shapes and structures in my Mar. 15, 2013 posting about them.)

Sacha will be seen (or perhaps the work will simply be presented by Max Shulaker?) next in Switzerland at a Mar. 25, 2013 workshop (FED ’13; Functionality-Enhanced Devices Workshop) at the EPFl (École Polytechnique Fédérale de Lausanne.

Tags: , , , , , , , , , , , , , , , , , , , ,
Posted in electronics, nanotechnology, robots | No Comments »

RoboEarth’s Rapyuta, a cloud engine for the robot internet

Tuesday, March 12th, 2013

Described in a 2011 BBC news item as an internet/wikipedia for robots only, RobotEarth was last mentioned here in a Feb. 14, 2011 posting (scroll down about 1/3 of the way) where I featured both the aforementioned BBC news item and a first person account of the project on the IEEE (Institute of Electrical and Electronics Engineering) Spectrum’s Automaton Robotics blog.

Today, Mar. 12, 2013, there’s a news release on EurekAlert about a new RoboEarth development,

Researchers of five European universities have developed a cloud-computing platform for robots. The platform allows robots connected to the Internet to directly access the powerful computational, storage, and communications infrastructure of modern data centers – the giant server farms behind the likes of Google, Facebook, and Amazon – for robotics tasks and robot learning.

With the development of the RoboEarth Cloud Engine the team continues their work towards creating an Internet for robots. The new platform extends earlier work on allowing robots to share knowledge with other robots via a WWW-style database, greatly speeding up robot learning and adaptation in complex tasks.

Here’s how the cloud engine is described,

The developed Platform as a Service (PaaS) for robots allows to perform complex functions like mapping, navigation, or processing of human voice commands in the cloud, at a fraction of the time required by robots’ on-board computers. By making enterprise-scale computing infrastructure available to any robot with a wireless connection, the researchers believe that the new computing platform will help pave the way towards lighter, cheaper, more intelligent robots.

“The RoboEarth Cloud Engine is particularly useful for mobile robots, such as drones or autonomous cars, which require lots of computation for navigation. It also offers significant benefits for robot co-workers, such as factory robots working alongside humans, which require large knowledge databases, and for the deployment of robot teams.” says Mohanarajah Gajamohan, researcher at the Swiss Federal Institute of Technology (ETH Zurich) and Technical Lead of the project.

“On-board computation reduces mobility and increases cost.”, says Dr. Heico Sandee, RoboEarth’s Program Manager at Eindhoven University of Technology in the Netherlands, “With the rapid increase in wireless data rates caused by the booming demand of mobile communications devices, more and more of a robot’s computational tasks can be moved into the cloud.”

Oddly, there’s never any mention of the name for the cloud engine project in the news release. I found the name (Rapyuta) on the RoboEarth website, from the home page,

Update: Join (or remotely watch) the Cloud Robotics Workshop at the EU Robotics Forum on Wednesday 20. March, 4-6pm CET. Details: http://www.roboearth.org/eurobotics2013

It is our pleasure to announce the first public release of Rapyuta: The RoboEarth Cloud Engine. Rapyuta is an open source cloud robotics platform for robots. It implements a Platform-as-a-Service (PaaS) framework designed specifically for robotics applications.

Rapyuta helps robots to offload heavy computation by providing secured customizable computing environments in the cloud. Robots can start their own computational environment, launch any computational node uploaded by the developer, and communicate with the launched nodes using the WebSockets protocol.

Interestingly, the final paragraph of today’s (Mar. 12, 2011) news release includes a statement about jobs,

While high-tech companies that heavily rely on data centers have been criticized for creating fewer jobs than traditional companies (e.g., Google or Facebook employ less than half the number of workers of General Electric or Hewlett-Packard per dollar in revenue), the researchers don’t believe that this new robotics platform should be cause for alarm. According to a recent study by the International Federation of Robotics and Metra Martech entitled “Positive Impact of Industrial Robots on Employment”, robots don’t kill jobs but rather tend to lead to an overall growth in jobs.

I’d like to see some more data about this business of robots creating jobs. In the meantime, there’s  more information about RoboEarth and the Rapyuta cloud engine in the links the news release provides to materials such as this video,

Unexpectedly, the narrator sounds like she might have been educated in Canada or the US.

Tags: , , , , , , , , , , ,
Posted in robots | No Comments »

Skills training: get ready for the robots

Tuesday, February 12th, 2013

If the boffins at the Massachusetts Institute of Technology (MIT) are right, soon we may be learning alongside robots and using the same techniques.  Helen Knight’s Feb. 11, 2013 news release for MIT highlights a recent study showing that robots, like humans, learn better if they cross-train. From the news release,

Robots are increasingly being used in the manufacturing industry to perform tasks that bring them into closer contact with humans. But while a great deal of work is being done to ensure robots and humans can operate safely side-by-side, more effort is needed to make robots smart enough to work effectively with people, says Julie Shah, an assistant professor of aeronautics and astronautics at MIT and head of the Interactive Robotics Group in the Computer Science and Artificial Intelligence Laboratory (CSAIL).

“People aren’t robots, they don’t do things the same way every single time,” Shah says. “And so there is a mismatch between the way we program robots to perform tasks in exactly the same way each time and what we need them to do if they are going to work in concert with people.”

Most existing research into making robots better team players is based on the concept of interactive reward, in which a human trainer gives a positive or negative response each time a robot performs a task.

However, human studies carried out by the military have shown that simply telling people they have done well or badly at a task is a very inefficient method of encouraging them to work well as a team.

Here’s the experiment Shah and her student performed,

So Shah and PhD student Stefanos Nikolaidis began to investigate whether techniques that have been shown to work well in training people could also be applied to mixed teams of humans and robots. One such technique, known as cross-training, sees team members swap roles with each other on given days. “This allows people to form a better idea of how their role affects their partner and how their partner’s role affects them,” Shah says.

In a paper to be presented at the International Conference on Human-Robot Interaction in Tokyo in March [2013], Shah and Nikolaidis will present the results of experiments they carried out with a mixed group of humans and robots, demonstrating that cross-training is an extremely effective team-building tool.

More specifically,

To allow robots to take part in the cross-training experiments, the pair first had to design a new algorithm to allow the devices to learn from their role-swapping experiences. So they modified existing reinforcement-learning algorithms to allow the robots to take in not only information from positive and negative rewards, but also information gained through demonstration. In this way, by watching their human counterparts switch roles to carry out their work, the robots were able to learn how the humans wanted them to perform the same task.

Each human-robot team then carried out a simulated task in a virtual environment, with half of the teams using the conventional interactive reward approach, and half using the cross-training technique of switching roles halfway through the session. Once the teams had completed this virtual training session, they were asked to carry out the task in the real world, but this time sticking to their own designated roles.

Shah and Nikolaidis found that the period in which human and robot were working at the same time — known as concurrent motion — increased by 71 percent in teams that had taken part in cross-training, compared to the interactive reward teams. They also found that the amount of time the humans spent doing nothing — while waiting for the robot to complete a stage of the task, for example — decreased by 41 percent.

What’s more, when the pair studied the robots themselves, they found that the learning algorithms recorded a much lower level of uncertainty about what their human teammate was likely to do next — a measure known as the entropy level — if they had been through cross-training.

Finally, when responding to a questionnaire after the experiment, human participants in cross-training were far more likely to say the robot had carried out the task according to their preferences than those in the reward-only group, and reported greater levels of trust in their robotic teammate. “This is the first evidence that human-robot teamwork is improved when a human and robot train together by switching roles, in a manner similar to effective human team training practices,” Nikolaidis says.

Shah believes this improvement in team performance could be due to the greater involvement of both parties in the cross-training process. “When the person trains the robot through reward it is one-way: The person says ‘good robot’ or the person says ‘bad robot,’ and it’s a very one-way passage of information,” Shah says. “But when you switch roles the person is better able to adapt to the robot’s capabilities and learn what it is likely to do, and so we think that it is adaptation on the person’s side that results in a better team performance.”

The work shows that strategies that are successful in improving interaction among humans can often do the same for humans and robots, says Kerstin Dautenhahn, a professor of artificial intelligence at the University of Hertfordshire in the U.K. “People easily attribute human characteristics to a robot and treat it socially, so it is not entirely surprising that this transfer from the human-human domain to the human-robot domain not only made the teamwork more efficient, but also enhanced the experience for the participants, in terms of trusting the robot,” Dautenhahn says.

The paper (Human-Robot Cross-Training: Computational Formulation, Modeling and Evaluation of a Human Team Training Strategy) written by Nikolaidis and Shah can be found here and the website for the conference (International Conference on Human-Robot Interaction [HRI]; 8th ACM [Association of Computing Machinery]/IEEE [Institute of Electrical and Electronics Engineers] Conference on Human-Robot Interaction) where it will be presented is here.

Tags: , , , , , , , , , , , , , ,
Posted in robots | No Comments »

Dragonflies: beautiful and smart according to Adelaide University (Australia) researchers

Friday, December 21st, 2012

[downloaded from http://en.wikipedia.org/wiki/File:Tiffany_dragonfly_hg.jpg] Attribution: pendant Dragonfly - replica from the lamp by Louis Comfort Tiffany (50 cm diameter, 20 cm hight, about 400 glass pieces), Own work, Hannes Grobe 19:33, 20 June 2007 (UTC) Permission Own work, share alike, attribution required (Creative Commons CC-BY-SA-2.5)

[downloaded from http://en.wikipedia.org/wiki/File:Tiffany_dragonfly_hg.jpg] Attribution: pendant Dragonfly – replica from the lamp by Louis Comfort Tiffany (50 cm diameter, 20 cm hight, about 400 glass pieces), Own work, Hannes Grobe 19:33, 20 June 2007 (UTC) Permission Own work, share alike, attribution required (Creative Commons CC-BY-SA-2.5)

Long a subject of inspiration for artists, dragonflies have now been observed to exhibit signs of selective intelligence similar to human selective intelligence. From the Dec. 20, 2012 news release on EurekAlert,

In a discovery that may prove important for cognitive science, our understanding of nature and applications for robot vision, researchers at the University of Adelaide have found evidence that the dragonfly is capable of higher-level thought processes when hunting its prey.

The discovery, to be published online today in the journal Current Biology [link to article which behind a paywall], is the first evidence that an invertebrate animal has brain cells for selective attention, which has so far only been demonstrated in primates.

Here’s how the researchers made the observation (from the EurekAlert news release),

Using a tiny glass probe with a tip that is only 60 nanometers wide – 1500 times smaller than the width of a human hair – the researchers have discovered neuron activity in the dragonfly’s brain that enables this selective attention.

They found that when presented with more than one visual target, the dragonfly brain cell ‘locks on’ to one target and behaves as if the other targets don’t exist.

“Selective attention is fundamental to humans’ ability to select and respond to one sensory stimulus in the presence of distractions,” Dr Wiederman [Dr. Steven Wiederman, University of Adelaide] says.

Wiederman’s research partner suggests this observation has the potential for a number of widespread applications,

“Recent studies reveal similar mechanisms at work in the primate brain, but you might expect it there. We weren’t expecting to find something so sophisticated in lowly insects from a group that’s been around for 325 million years.

“We believe our work will appeal to neuroscientists and engineers alike. For example, it could be used as a model system for robotic vision. Because the insect brain is simple and accessible, future work may allow us to fully understand the underlying network of neurons and copy it into intelligent robots,” he [Associate Professor David O'Carroll, University of Adelaide] says.

You can find more information including pictures and a video in the Dec. 21, 2012 University of Adelaide news release.

Tags: , , , , , , , , ,
Posted in biomimcry, medicine, nanotechnology, robots | No Comments »

Swarming robot droplets

Monday, December 17th, 2012

The robot droplets are a bit bigger than you might expect, the size of ping pong balls, but the idea is intriguing and for those who’ve read Michael Crichton’s book, Prey, it could seem quite disturbing (from the University of Colorado Boulder multimedia page for ‘tiny robots’),

For anyone unfamiliar with Crichton’s Prey, here’s an excerpt from the Wikipedia entry about the book which features nanobots operating as a swarm,

… As a result, hazardous elements such as the assemblers, the bacteria, and the nanobots were blown into the desert, evolving and eventually forming autonomous swarms. These swarms appear to be solar-powered and self-sufficient, reproducing and evolving rapidly. The swarms exhibit predatory behavior, attacking and killing animals in the wild, using code that Jack himself worked on. Most alarmingly, the swarms seem to possess rudimentary intelligence, the ability to quickly learn and to innovate. The swarms tend to wander around the fab plant during the day but quickly leave when strong winds blow or night falls.

The Dec. 14, 2012 posting by Alan on the Science Business website describes,

A computer science lab at University of Colorado in Boulder is building a miniature, limited-function robot designed to work in a swarm of similar devices. Computer science professor Nikolaus Correll and colleagues are building these small devices that they call droplets as building blocks for increasingly complex systems.

A University of Colorado Boulder Dec. 14, 2012 news release provides more details,

Correll and his computer science research team, including research associate Dustin Reishus and professional research assistant Nick Farrow, have developed a basic robotic building block, which he hopes to reproduce in large quantities to develop increasingly complex systems.

Recently the team created a swarm of 20 robots, each the size of a pingpong ball, which they call “droplets.” When the droplets swarm together, Correll said, they form a “liquid that thinks.”

To accelerate the pace of innovation, he has created a lab where students can explore and develop new applications of robotics with basic, inexpensive tools.

Similar to the fictional “nanomorphs” depicted in the “Terminator” films, large swarms of intelligent robotic devices could be used for a range of tasks. Swarms of robots could be unleashed to contain an oil spill or to self-assemble into a piece of hardware after being launched separately into space, Correll said.

Correll plans to use the droplets to demonstrate self-assembly and swarm-intelligent behaviors such as pattern recognition, sensor-based motion and adaptive shape change. These behaviors could then be transferred to large swarms for water- or air-based tasks.

Correll hopes to create a design methodology for aggregating the droplets into more complex behaviors such as assembling parts of a large space telescope or an aircraft.

There’s also talk about creating gardens in space,

He [Correll] also is continuing work on robotic garden technology he developed at the Massachusetts Institute of Technology in 2009. Correll has been working with Joseph Tanner in CU-Boulder’s aerospace engineering sciences department to further develop the technology, involving autonomous sensors and robots that can tend gardens, in conjunction with a model of a long-term space habitat being built by students.

Correll says there is virtually no limit to what might be created through distributed intelligence systems.

“Every living organism is made from a swarm of collaborating cells,” he said. “Perhaps some day, our swarms will colonize space where they will assemble habitats and lush gardens for future space explorers.”

The scientists don’t seem to harbour any trepidations, I guess they’re leaving that to the writers.

Tags: , , , , , , , , , , , , , , ,
Posted in nanotechnology, robots, science | No Comments »

Existential risk

Monday, November 26th, 2012

The idea that robots of one kind or another (e.g. nanobots eating up the world and leaving grey goo, Cylons in both versions of Battlestar Galactica trying to exterminate humans, etc.) will take over the world and find humans unnecessary  isn’t especially new in works of fiction. It’s not always mentioned directly but the underlying anxiety often has to do with intelligence and concerns over an ‘explosion of intelligence’. The question it raises,’ what if our machines/creations become more intelligent than humans?’ has been described as existential risk. According to a Nov. 25, 2012 article by Sylvia Hui for Huffington Post, a group of eminent philosophers and scientists at the University of Cambridge are proposing to found a Centre for the Study of Existential Risk,

Could computers become cleverer than humans and take over the world? Or is that just the stuff of science fiction?

Philosophers and scientists at Britain’s Cambridge University think the question deserves serious study. A proposed Center for the Study of Existential Risk will bring together experts to consider the ways in which super intelligent technology, including artificial intelligence, could “threaten our own existence,” the institution said Sunday.

“In the case of artificial intelligence, it seems a reasonable prediction that some time in this or the next century intelligence will escape from the constraints of biology,” Cambridge philosophy professor Huw Price said.

When that happens, “we’re no longer the smartest things around,” he said, and will risk being at the mercy of “machines that are not malicious, but machines whose interests don’t include us.”

Price along with Martin Rees, Emeritus Professor of Cosmology and Astrophysics, and Jaan Tallinn, Co-Founder of Skype, are the driving forces behind this proposed new centre at Cambridge University. From the Cambridge Project for Existential Risk webpage,

Many scientists are concerned that developments in human technology may soon pose new, extinction-level risks to our species as a whole. Such dangers have been suggested from progress in AI, from developments in biotechnology and artificial life, from nanotechnology, and from possible extreme effects of anthropogenic climate change. The seriousness of these risks is difficult to assess, but that in itself seems a cause for concern, given how much is at stake. …

The Cambridge Project for Existential Risk — a joint initiative between a philosopher, a scientist, and a software entrepreneur — begins with the conviction that these issues require a great deal more scientific investigation than they presently receive. Our aim is to establish within the University of Cambridge a multidisciplinary research centre dedicated to the study and mitigation of risks of this kind.

Price and Tallinn co-wrote an Aug. 6, 2012 article for the Australia-based, The Conversation website, about their concerns,

We know how to deal with suspicious packages – as carefully as possible! These days, we let robots take the risk. But what if the robots are the risk? Some commentators argue we should be treating AI (artificial intelligence) as a suspicious package, because it might eventually blow up in our faces. Should we be worried?

Asked whether there will ever be computers as smart as people, the US mathematician and sci-fi author Vernor Vinge replied: “Yes, but only briefly”.

He meant that once computers get to this level, there’s nothing to prevent them getting a lot further very rapidly. Vinge christened this sudden explosion of intelligence the “technological singularity”, and thought that it was unlikely to be good news, from a human point of view.

Was Vinge right, and if so what should we do about it? Unlike typical suspicious parcels, after all, what the future of AI holds is up to us, at least to some extent. Are there things we can do now to make sure it’s not a bomb (or a good bomb rather than a bad bomb, perhaps)?

It appears Price, Rees, and Tallinn are not the only concerned parties, from the Nov. 25, 2012 research news piece on the Cambridge University website,

With luminaries in science, policy, law, risk and computing from across the University and beyond signing up to become advisors, the project is, even in its earliest days, gathering momentum. “The basic philosophy is that we should be taking seriously the fact that we are getting to the point where our technologies have the potential to threaten our own existence – in a way that they simply haven’t up to now, in human history,” says Price. “We should be investing a little of our intellectual resources in shifting some probability from bad outcomes to good ones.”

Price acknowledges that some of these ideas can seem far-fetched, the stuff of science fiction, but insists that that’s part of the point.

According to the Huffington Post article by Lui, they expect to launch the centre next year (2013). In the meantime, for anyone who’s looking for more information about the ‘intelligence explosion’ or  ‘singularity’ as it’s also known, there’s a Wikipedia essay on the topic.  Also, you may want to stay tuned to this channel (blog) as I expect to have some news about an artificial intelligence project based at the University of Waterloo (Ontario, Canada) and headed by Chris Eliasmith at the university’s Centre for Theoretical Neuroscience, later this week.

Tags: , , , , , , , , , , , , ,
Posted in robots, science, science philosophy | 1 Comment »

New hydrogels make greater elasticity in tissue engineering possible

Thursday, September 6th, 2012

A team from Harvard University have developed a technique for creating hydrogels that could be used effective in tissue engineering projects. From the Sept. 5, 2012 news release on EurekAlert,

A team of experts in mechanics, materials science, and tissue engineering at Harvard have created an extremely stretchy and tough gel that may pave the way to replacing damaged cartilage in human joints.

Called a hydrogel, because its main ingredient is water, the new material is a hybrid of two weak gels that combine to create something much stronger. Not only can this new gel stretch to 21 times its original length, but it is also exceptionally tough, self-healing, and biocompatible—a valuable collection of attributes that opens up new opportunities in medicine and tissue engineering.

Here’s an image of the hydrogel provided by the researchers,

The researchers pinned both ends of the new gel in clamps and stretched it to 21 times its initial length before it broke. Credit: Photo courtesy of Jeong-Yun Sun

The Sept. 5, 2012 news item on ScienceDaily has some comments from the researcher,

“Conventional hydrogels are very weak and brittle — imagine a spoon breaking through jelly,” explains lead author Jeong-Yun Sun, a postdoctoral fellow at the Harvard School of Engineering and Applied Sciences (SEAS). “But because they are water-based and biocompatible, people would like to use them for some very challenging applications like artificial cartilage or spinal disks. For a gel to work in those settings, it has to be able to stretch and expand under compression and tension without breaking.”

To create the tough new hydrogel, they combined two common polymers. The primary component is polyacrylamide, known for its use in soft contact lenses and as the electrophoresis gel that separates DNA fragments in biology labs; the second component is alginate, a seaweed extract that is frequently used to thicken food.

Separately, these gels are both quite weak — alginate, for instance, can stretch to only 1.2 times its length before it breaks. Combined in an 8:1 ratio, however, the two polymers form a complex network of crosslinked chains that reinforce one another. The chemical structure of this network allows the molecules to pull apart very slightly over a large area instead of allowing the gel to crack.

The alginate portion of the gel consists of polymer chains that form weak ionic bonds with one another, capturing calcium ions (added to the water) in the process. When the gel is stretched, some of these bonds between chains break — or “unzip,” as the researchers put it — releasing the calcium. As a result, the gel expands slightly, but the polymer chains themselves remain intact. Meanwhile, the polyacrylamide chains form a grid-like structure that bonds covalently (very tightly) with the alginate chains.

Therefore, if the gel acquires a tiny crack as it stretches, the polyacrylamide grid helps to spread the pulling force over a large area, tugging on the alginate’s ionic bonds and unzipping them here and there. The research team showed that even with a huge crack, a critically large hole, the hybrid gel can still stretch to 17 times its initial length.

Importantly, the new hydrogel is capable of maintaining its elasticity and toughness over multiple stretches.

Anyone can see that the ability to stretch, self-heal and stretch mimics the body’s own processes and that materials which can mimic those processes are very promising. From the news item on ScienceDaily,

Beyond artificial cartilage, the researchers suggest that the new hydrogel could be used in soft robotics, optics, artificial muscle, as a tough protective covering for wounds, or “any other place where we need hydrogels of high stretchability and high toughness.”

If you’re interested, there are still more details in the news release on EurekAlert or in the news item on ScienceDaily.

Tags: , , , , , ,
Posted in medicine, nanotechnology, robots | No Comments »

COllaborative Network for Training in Electronic Skin Technology (CONTEST) looking for twelve researchers

Tuesday, August 21st, 2012

The CONTEST (COllaborative Network for Training in Electronic Skin TechnologyCOllaborative Network for Training in Electronic Skin Technology) project was launched today in Italy. According to the Aug. 21, 2012 news item on Nanowerk,

“Flexible electronics” is one of the most significant challenges in the field of future electronics. The possibility of realizing flexible and bendable electronic circuits, that can be rolled up, twisted or inserted in films around objects, would introduce a range of infinite applications in multiple fields, including healthcare, robotics and energy.

In this area, the Fondazione Bruno Kessler of Trento will coordinate the CONTEST project (COllaborative Network for Training in Electronic Skin Technology), an Initial Training Network (ITN) Marie Curie project funded by the European Commission involving European research, academic and business players. These include seven full partners (Fondazione Bruno Kessler, Italy; ST Microelectronics, Italy; Technical University Munich, Germany; Fraunhofer EMFT, Germany; University College London, UK; Imperial College London, UK; and Shadow Robotics Company, UK) and two associate partners (University of Cambridge, UK, and University of Tokyo, Japan).

The CONTEST project page at the Fondazione Bruno Kessler website offers more details,

At the heart of the CONTEST programme lies the multidisciplinary research training of young researchers. The CONTEST network will recruit twelve excellent Early-Stage Researchers (e.g. PhD students) and two Experienced Researchers (e.g. Post-Doc fellows). Information for submitting applications is available at the project’s website: http://www.contest-itn.eu/.
CONTEST activities will be coordinated by Ravinder S. Dahiya, researcher at the Bio-MEMS Unit (BIO-Micro-Electro-Mechanical-Systems) of  the Center for Materials and Microsystems (Fondazione Bruno Kessler) and by Leandro Lorenzelli, head of the Bio-MEMS Unit.
“The disruptive flexible electronics technology – says Ravinder S. Dahiya – will create change and improve the electronic market landscape and usher in a new revolution in multifunctional electronics. It will transform to an unprecedented degree our view of electronics and how we, as a society, interact with intelligent and responsive systems.”
“The investigation, in a very multidisciplinary framework, of technological approaches for thin flexible components – explains Leandro Lorenzelli - will generate new paradigms and concepts for microelectronic devices and systems with new functionalities tailored to the needs of a wide range of applications including robotics, biomedical instrumentations and smart cities.”

Here’s more about the 12 researchers they’re recruiting, excerpted from the Job Openings page on the CONTEST project website (Note: I have removed some links),

We have been awarded a large interdisciplinary project on electronic skin and applications, called CONTEST (COllaborative Network for Training in Electronic Skin Technology). We are therefore looking for 12 excellent Early-Stage Researchers (e.g. PhD students) and 2 Experienced Researchers (e.g. Post-Doc), associated to:

  • Fondazione Bruno Kessler, Trento, Italy (2 Early-Stage Researcher positions on silicon based flexible sensors (e.g. touch sensors), electronic circuits and 1 Experienced Researcher position on system integration)  …,
  • ST Microelectronics, Catania, Italy (2 Early-Stage Researcher positions on chemical/physical sensors on flexible substrates, and metal patterned substrates for integrating flexible sensing elements)…,
  • Technical University Munich, Germany (3 Early-Stage Researcher positions on organic semiconductor based electronics devices and circuits, modeling of flexible devices and sensors … , and artificial skin in humanoids…,
  • Fraunhofer EMFT, Munich, Germany (1 Early-Stage Researcher position on assembly on film substrates and foil integration as well as 1 Experienced Researcher position on reliability and ESD issues of components during flex integration) … ,
  • University College London, UK (2 Early-Stage Researcher positions on organic semiconductor based interconnects, solutions processed sensors, alternative on-skin energy schemes, patterning of e-skin and stretchable interconnects using blends of graphene in polymeric materials …
  • Imperial College London, UK (1 Early-Stage Researcher position on human sensori-motor control and robotics) …, and
  • Shadow Robotics Company, UK (1 Early-Stage Researcher position on biorobotics and mechatronics) ….

Mobility rules apply to all these positions. Researchers can be of any nationality. They are required to undertake trans-national mobility (i.e. move from one country to another) when taking up their appointment. One general rule applies to the appointment of researchers: At the time of recruitment by the host organization, researchers must not have resided or carried out their main activity (work, studies, etc.) in the country of their host organization (i.e. recruiting institute) for more than 12 months in the 3 years immediately prior to the reference date. Short stays such as holidays and/or compulsory national service are not taken into account.

Good luck to all who apply! Priority will be given to applications received by Sept. 30, 2012.

Tags: , , , , , , , , , , , , , , , , , , ,
Posted in electronics, nanotechnology, robots, science | No Comments »

« Older Entries