Robots may not be Human, but They can Feel

A team at the Georgia Institute of Technology have created an electronic skin that allows a robotic arm, built by Meka Robotics, to feel its way through clutter and interpret its immediate environment by use of an algorithm developed by Charlie Kemp and colleagues.

The invention will be presented at the International Conference on Rehabilitation Robotics in Seattle, Washington this month. The robot arm is seen to have great applications; so far it has been controlled by a quadriplegic man (paralysis in both arms and legs) using head movements, who used the technology to place a blanket over himself and wipe his face.

The "flexible, electronic skin" is 'peppered' with a whopping 384 sensors, allowing the robot to detect extremely light touches; then a decision on the arm's next series of movements is made from calculations by an algorithm also developed by Kemp and the team.

Robots are usually designed to avoid obstacles in their path or navigate away from anything it comes into contact with; in this case, the extreme sensitivity of the arm allows it to gently move objects out of the way or plan the shortest route to its destination without meeting anything that will resist it too much.

The New Scientist suggests that the "sensitivity level can be changed to match the task, from picking delicate fruit to searching for a person buried in rubble." Alternatively, "underwater robots could feel their way along as a means of navigating small, dark spaces."

References: The New Scientist, digitaltrends.com

Good News! China's Eco-Attitude

Back in 2012, China estimated that they would reach their carbon dioxide emissions peak in 2030. Now we are looking at emissions peaking in 2025, with a cap on total emissions by 2016.

As the largest emitter of carbon dioxide, China has already made promises to reduce its production levels. They have endeavoured to cut the "emissions associated with every generated dollar of GDP by 45 percent between 2005 and 2020."

The estimated increase in China's emissions before the hopeful peak in 2025 is a rise of 15 to 20 percent.

Their plans to ensure this peak at such a surprisingly early stage requires placing caps on emissions, and a carbon-trading scheme involving companies responsible for 38% of Shenzhen's total emissions. Shenzhen is a sub-provincial city and one of China's most populated and wealthy cities. As a hub for Chinese manufacturing, Shenzhen is now one of the world's fastest-growing cities; any plans to reduce the area carbon dioxide mission will be a huge task, but one that, if successful, will make a huge difference.

Carbon-trading can be applied to countries and companies exchanging their pollution rights, but in this case, China is planning on allowing individual companies to sell and buy unused pollution rights. A company that does not pollute a great deal can sell their 'spare rights' to companies that tend to pollute more. There is now a financial incentive to reducing a company's pollution levels, and will encourage companies to not exceed a baseline for emissions.

These schemes will encourage the construction of cleaner natural gas and nuclear plants, and development of renewable energies. In fact, China has already earned the title for producing the most solar panels and wind turbines in the world.

In the past, there may have been reason to doubt that these promises will be kept to, but there's no denying that so far, China's estimates for their peak are looking perfectly achievable.

By 2113, every Child will have a Velociroach

The VELOCIRoACH is a 30-gram cardboard hexapod (a six-legged walking robot), measuring 10cm long, and can run up to 2.7m/s, making it the ‘fastest legged robot built to date’.

 

Strictly speaking, a robot called LS3 holds the record for the fastest self-powered robot with a top speed of 3.2m/s. But relative to its tiny size, VELOCIRoACH has an incredible ability and because of this, it is able to cross a distance 26 times that of its length in just one second.

 

The robot isn’t named after a cockroach for nothing; VELOCIRoACH’s inventors modelled its structure on the anatomy of cockroaches, which have thin, springy C-shaped legs allowing the robot to touch the ground 15 times per second.

 

Three out of its six legs are always touching the ground, in a tripod formation, to keep it stable, and despite being mainly cardboard, the 10cm bot can carry up to 4 times its own weight.

 

The VELOCIRoACH 2.0, as it were, is planned to mimic a cockroach even more closely by withstanding its arch nemesis, the human foot.

I want one; they are so COOL. Anybody else fancy a VELOCIRoACH scuttling around their home? I can't imagine why you wouldn't!

 

 

 

References: NewScientist, robotics.eecs.berkeley.edu, YouTube (video)

 

Physics vs Biology in the Cure for Cancer

NCI Campus, Rockville, Maryland

From 2005-2012, the National Cancer Institute (NCI) in the US averaged an amount of $4.9 billion each year being put into cancer-related research.

Cancer Research UK spent £332 million on research activity in the 2011-2012 financial year.

Cancer research and treatment development consumes massive amounts of funding every year, but the cure for this universally-feared disease remains just out of reach.

Cancer cells, to a biologist, are pockets of chemical reactions and processes, capable of causing significant damage to healthy, living cells and genetic mutations in their cell recruits. Despite substantial funding which has fed into this all-important research, the US, for example, has seen a 5% decrease in cancer-related deaths since 1950. Although this is still an incredible number of lives saved, what more can be done to save future lives?

Perhaps the key to unlocking the mysterious fix lies with not a cancer biologist, but with a new type of mind - a physicist's mind.

In 2008, the NCI built 12 centres for physical science and oncology, designed for physicists, engineers and mathematicians to shed new light on cancerous cell behaviour.

Cells may be living things, but a physicist will consider other things than it's matter and behaviour: how about a cell's shape? Features in its structure such as pumps and levers? Properties of the membrane, the texture and design of the cell surface? "Many of these properties are known to change systematically as cancer progresses in malignancy."

Metastasis of the cancerous cells from the primary tumour.

Metastasis is the spread of cancer from its original position to another organ of the body. It is this which makes cancer so deadly.

Even if the primary tumour is removed, there is always the possibility that a new tumour could form and cause problems years later, due to a cancerous cell's ability to spread by entering the blood's circulation.

Four years after NCI proposed that physicists take a look at cancer, discoveries have been made concerning how the shape of a cancer cell changes during metastasis. Some are able to release "little molecular grappling hooks" or 'cadherins' to grip onto a blood vessel wall and 'nest' in the nearest organ.

Areolar extracellular matrix.

The new organ tissue may seem foreign but new research shows that cancer cells are able to alter the structure of the foreign organ's extracellular matrix - this section of tissue provides structural and defensive support to important tissues and organs.

So perhaps with the combined powers of biological and physical scientists, research for the treatment and ultimately cure for cancer will make some interesting leaps and bounds in the right direction. I think we should bring the three streams of science together more often (let's not forget Chemistry!), allowing different perspectives to be directed at the same problem. Surely things would be solved faster that way? No?

References: New Scientist, Wikipedia, National Cancer Institute, Cancer Research UK

I Wonder if Mario Was Dreamt Up by a Robot..?

Artificial Intelligence and Robots. All sounds a bit sci-fi, doesn't it? That may be, but there is some pretty cool stuff being done in the world by robotics and AI at this very moment...

Angelina, an Artificial Intelligence system built to design video games by creator Michael Cook, of Imperial College London, released her first game last December, A Puzzling Present.

Cook begins Angelina’s design process by presenting her with a game level that has no solution. Angelina then redesigns the level by applying ideas used in existing games, altering them, and adding further objects and obstacles, until she finds a solution. This may not seem too impressive, but what makes Angelina stand out in the field of AI is that it is able to invent its own additions to the game without outside help.

One example found an error in the initial level which Cook invented. This error enabled the game character to teleport inside a wall and yet still be able to jump. Angelina fixed this bug and modified the code to create a ‘wall-jump’ technique, allowing the character to climb a vertical wall by repeatedly jumping and teleporting up the surface.

Angelina is capable of finding multiple solutions to game levels, which can be used to help game-developers make their programs appropriately easier and harder. It will also be able to fix errors in games and offer new ideas for features of video games. Cook sees the development of AI systems like Angelina as a huge help in the gaming industry, which is worth approximately $50 billion worldwide, and potentially $70 billion by 2017. (Crikey, that's a lot of coppers...)

Anybody know of any other interesting AI systems or robots?

The Downfall of the Dinos... How Much Do We Really Know?

I am co-founder of my school's e-newspaper, which myself and a few like-minded friends set up just over a year ago with the aim of sharing important, relevant and also not-so-relevant-and-frankly-quite-wacky news stories with our school.

I love being a part of this and even more so, I love being able to research scientific and engineering developments for our e-paper. (As a side note, if anybody enjoys writing, browsing the internet and having an excuse to frequently meet up with friends and chow down on snackage, I highly recommend starting one yourself!)

I volunteered to compose our last issue's Big Article for the front page and found out some pretty interesting stuff about the dinos. I thought you guys might be interested to know!

251 million years ago, at the end of the Permian period, 90% of the world’s species became extinct. Why?

The current dominating theory is that the mass extinction was caused by volcanic eruptions across a vast expanse of land, now known as Siberia. This theory has never fully satisfied scientists; Daniel Rothman from MIT has been studying Permian rock samples and has announced that carbon levels around this time increased too quickly to have been caused by merely volcanoes. A likely cause for the concentration of carbon compounds is microbes.

Rothman and his team analysed the genetic information of a microbe called Methanosarcina*, a methane-producing microorganism accountable for the majority of today’s methane and discovered that it developed its ability to generate methane about 251 million years ago.

One catch is that Methanosarcina needs huge quantities of nickel to produce methane at such a rate. Siberian lava is rich in nickel and nickel levels shot up almost exactly 251 million years ago, which seems to suggest that volcanic eruptions triggered the production of methane by the Methanosarcina, which in turn triggered the extinction of so many species.

Anthony Barnosky from the University of California says, “It's a fascinating idea that the evolution of a new life form led to an extinction.” We still don’t know what exactly happened all those years ago, but we are getting closer, one microbe at a time. I'm not sure which theory is most likely, but this is quite compelling, don't you think?

*Frankly, this is far too difficult to pronounce. I propose we nickname this microbe Jeffrey, or Orlando. Thoughts? :D