La macchina di Turing

    E-Traces, shoes record the ballet dancers movements

    E-Traces Arduino per ballerine, Close-up Engineering - Credits:

    E-Traces stands for “Electronic Traces” and it is an interactive project created with the aim of allowing ballet dancers reproduce their movements in digital “figures” using a customized mobile application.
    The prototype was developed by product designer Lesia Trubat combining technological and craftsmanship expertise and using Arduino Lilypad, force sensors and accelerometers.

    The Electronic Traces concept is based on capture of dance movements transforming them into “visual sensations” through the use of modern technology. To do this -explain the authors of the project- we focused on the ballet shoes that, through contact with the floor and thanks to technology Arduino Lilypad technology , record the pressure and the movements of the feet of the dancers and send signals to an electronic device. A special application will allow us to display graphically the data and customize them for individual user.

    With this technology, the user will be able to see all the performed movements in video format, they can extract images and even print them. The dancers will be able to interpret their movements and correct them or compare them with those of other dancers.


    Arduino LilyPad

    It is a microcontroller designated for wearable technology and “electronic textiles” (e-textiles). It can be sewn to fabric and, as with the other Arduino circuit boards, can be equipped with power supplies, sensors and actuators. The board is based on ATmega168V (the low-power version of the ATmega168) or ATmega328V. Arduino LilyPad  was designed and developed by Leah Buechley and SparkFun Electronics.

    Arduino LilyPad has a circular shape, about 50mm in diameter. It has a thickness of 8mm and being designed to be worn and, with extreme attention, it can also be washed.

    Gallery images credits:

    Graphene, a material for the future

    For some time we talk about Graphene, but now it seems that something is happening for real.

    10 years after the discovery of this revolutionary material by the two Russian researchers (Andre Geim and Kostya Novoselov, for which they won the Nobel Prize in 2010), the graphene is still the ‘only material in two dimensions, the thinnest ever created (in addition to being the most resistant) and obtainable from the same material it is made of a tip of pencil, graphite.

    But, how the two researchers obtained these thin layers of graphene?

    They took a graphite block and used a tape to remove small fragments of the mineral. Repeating the operation several times on the same fragments and pressing the adhesive tape on a silicon substrate, it was possible to obtain very thin layers, some of which, examined with a solution of sulfuric and nitric acid, showed a thickness of a single atom, or the same size that we get if we divide the section of a human hair 10,000 parties.

    What is the use of Graphene?

    “I dont know. It ‘s like to submit a piece of plastic to a man than a century ago and ask what you can do. A bit ‘of everything, I think “

    Andre Geim

    These are some of the many properties of graphene:

    • Mechanical strength 50 times higher than that of ‘steel;
    • More than twice the thermal conductivity of the diamond;
    • Density equal to half of ‘aluminum, and so dense that not even the’ helium, the smallest gas atom, can pass through it;
    • High acquiescence, or the ability to be shaped at will for any use without the risk of breaking it;
    • Resistant to changes in temperature and pH.

    Some of the fields of application of this material…

    • The “Massachusetts Institute of Technology” in the United States has carried out an experiment in reverse osmosis with graphene, reaching excellent results. The molecular structure of graphene allows you to create any size of the holes on its surface and for this reason it was possible to pass the ‘pure water on one side and salts from’ other. There ‘s nothing new in this experiment, only with the’ use of this material will be possible to have much smaller equipment, an energy cost equal to almost zero water filtration and water purification.
    • The combination of its mechanical properties with electric ones they can be used in electronics flexible and foldable, with the creation of devices that fold back on themselves, that you can roll up or put on your wrist. The electrons can travel in this material with a speed close to that of light, making it the replacement of copper in our computer. It is on this street, Intel and IBM are investigating solutions to solve the problem related to the technologies in silicon which, although superior to any other, they produce a high amount of heat. Graphene, therefore, for its outstanding thermal properties could solve these problems. In addition, the exceptional mobility of the charges, accompanied by appropriate architectural solutions, may allow the realization of ultra-low power transistors for portable applications such as mobile phones or PDAs, which could be recharged once a month, rather than at intervals of a few days, besides the fact that the batteries of mobile phones will be able to charge much more rapidly (it is estimated at around 15 minutes).
    • New solar panels are lighter and will be fully biocompatible carbon. Will be eliminated so the most fragile and expensive made ​​with indium-tin oxide, a material that is more and more difficult in our planet. There will also be more efficient, easier to recycle and consist of two solar cells sandwiched between two layers of graphene. The light passes through the graphene layers and hits the photovoltaic cell, with the result of generating electricity which is then transported from the graphene.
    • Its use must be from aviation (aircraft so lightweight that consume little fuel) to sports.

    What are the costs?

    The ‘international interest is too large, so that the’ European Union has financed one billion euro project to bring it on the market.
    Various techniques have been developed for the production of graphene, but at the moment there is no effective and inexpensive method for obtaining large sheets. It is estimated that the cost to produce one kilogram of graphene are around 30-35,000 Euros.

    iCub, the baby-robot stands now

    iCub is an android robot  built by the Italian Institute of Technology (IIT ) in Genoa. It is 104 cm tall , weighs 22 kg and remember, for aesthetics and functionality, a child of about four years.

    iCub has been developed in conjunction with the RobotCub Consortium, a joint venture of some European universities. The major purpose of this platform and hardware is to study cognition through the implementation of algorithms motivated by biology.

    The project is open-source both software,  available for free and unencrypted, and hardware, specifically described in its components, with pieces available in the market .


    53 degrees of freedom

    • 7 for each robotic arm
    • 9 for each robotic hand (3 for the thumb, 2 for the forefinger, 2 for the middle finger, 1 for couple ringfinge-littlefinge, 1 for the abduction / adduction)
    • 6 for head movements
    • 3 for the chest and spine
    • 6 for each leg robotics


    • Crawl ( crawling ) .
    • Basic functions of visual processing .
    • Low-level sensors for the control of eye movement , inertia and body proprioception .
    • High resolution camera that can retransmit the images.
    • Good ability to right-handed manipulation .
    • ITalk : programs for the progressive learning of the language by the robot, in a random object and situation – related

    The humanoid robot is now learning to stand and keep the balance even physical interaction with people. Thanks to the artificial skin that allows it to have 4000 sensitive points on the whole body is capable of measuring at each instant the contacts and the forces that it receives from the outside, responding with appropriate movements to maintain balance.

    These new capabilities will be useful when, in the near future, iCub cohabit with humans in domestic environments and will have to move safely for themselves and for others. This result was achieved thanks to the efforts of researchers from IIT and, in particular, the European Project Codyco, coordinated by Francesco Nori, Department of Robotics, Brain and Cognitive Sciences of IIT.

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