There are some World Cup Football Teams who you may think need a miracle in order to win the coveted World Cup. But a miracle, of sorts, will take place on the football pitch of the Arena Corinthians in São Paulo at the opening ceremony of the World Cup at 5pm 12 June (local time). A young Brazilian will take a kick of a football on the centre spot.
But this is no ordinary young man, nor is the kick trivial. The boy, yet to be chosen from a shortlist of nine aged between 20 and 40,will be a paraplegic. He will rise from his wheelchair and walk to the midfield and then kick the ball. How?
It’s down to Miguel Nicolelis and his team of neuro-engineers and scientists at Duke University in North Carolina. And if the event works as intended, it should spell the end for wheelchairs, and the evolution of mind-controlled exoskeleton robots. Here’s a picture of the robot:
The mind-controlled robotic exoskeleton is a complex robotic suit built from lightweight alloys and powered by hydraulics. When a paraplegic person straps themselves in, the machine does the job that their leg muscles no longer can. But there are no buttons levers or controls to tell the robot what to do. Only the human brain.
The exoskeleton is the culmination of years of work by an international team of scientists and engineers on the Walk Again project. The robotics work was coordinated by Gordon Cheng at the Technical University in Munich and the French researchers built the exoskeleton. Nicolelis’ team focused on what many say is the most difficult bit; ways to read people’s brain waves, and use those signals to control robotic limbs.
To operate the exoskeleton, the person is helped into the suit and given a cap to wear that is fitted with electrodes to pick up their brain waves. These signals are passed to a computer worn in a backpack, where they are decoded and used to move hydraulic drivers on the suit. There’s a battery that powers everything, with a two hour life before it needs re-charging.
The operator’s feet rest on plates which have sensors to detect when contact is made with the ground. With each footstep, a signal is transmitted to a vibrating device sewn into the forearm of the wearer’s shirt. The device fools the brain into thinking that the sensation came from their foot. In virtual reality simulations, patients felt that their legs were moving and touching something. Here’s a diagram showing the details.
Last month, Nicolelis and his colleagues went to some football matches in São Paulo to check whether mobile phone radiation from the crowds might interfere with the suit. Electromagnetic waves could make the exoskeleton misbehave, but they were reassured.
This is ground-breaking robotic/artificial intelligence/mind-control technology all rolled into one: Let’s keep our fingers crossed that we will all witness the miracle first kick of the World Cup on 12 June.
In the 1950’s comics and sci-fi films were renown for portraying Robots as being evil, running amok and like Prometheus Unbound (Frankenstein’s monster) biting the hand that created and fed them. While there were some benign robots, the theme of treacherous robots continued unabated, think HAL 9000 in 2001:A Space Odyssey, I robot (the book and film) , and even Transformers where robots battled it out on our behalves with us looking on like dim-witted spectators.
But here in 2014, the reality is quite different. Robots are getting more and more sophisticated and all are helping, not hindering mankind. Examples you want? Here’s one. He (or she?) is called QB and is being sold by the company Anybots-
In a nutshell it is a remotely controlled, self-balancing, “virtual presence robot/avatar”. If you want more catch-phrases for this form of communication, how about “mobile telepresence”.
The Anybot is controlled through a browser-based interface and allows you to be in virtual attendance at any event or meeting that you can’t make in person. Anybots are equipped with a speaker, camera, and video screen. They connect to the Internet over Wi-Fi and you activate them as well as control them remotely from your computer. Hook up a camera to your computer, you can show live video of yourself while interacting through the robot in a remote location anywhere in the world.
How to steer your robot? You use your keyboards four arrow keys to make it turn or go forward & back. A built-in guidance system augments the driver’s commands, making it easy to safely avoid people or objects and move through narrow doorways. It has a ground-breaking balancing system and unlike your home computer or server at work, won’t fall over!
Practical examples? A doctor could visit their patient from a remote location and those who are home-bound could use this robot to attend social gatherings, be they in or out-of-doors. The Anybot could be used in education to allow sick students to still participate with their classmates in and out of the classroom, as well as allowing educators the ability to check in or give lectures when they are away from the classroom.
There’s a lot of additional features and software you can add to make your Anybot individual and tailor-made for your needs.
So far, none of them have gone beserk and attacked humans!