snake robot for spying ppt

[sindhu]

A military reconnaissance robot being developed at a British lab can keep moving even if it gets damaged on the battlefield. When any of the snake-like robot s muscle segments are damaged, clever software evolves a different way for it to wriggle across any terrain.

The serpentine spy is a research project funded by aerospace company BAE Systems to make a low-cost military robot that can be dropped out of helicopters to carry out reconnaissance missions. Because it is not wheeled, the low-profile, ground-hugging snakebot should make a versatile battlefield spy. The team behind it has also developed a shape-changing antenna that broadcasts high-quality video and audio.

Anatomy of a snakebot
Anatomy of a snakebot
A self-healing robot has long been a dream of robotics engineers, not least because the machines are notoriously unreliable and absolutely terrible at dealing with unforeseen circumstances.

When a dog loses a leg it s got a clever enough brain to allow it to adapt, says computer scientist Peter Bentley at University College London. But robots still lack this adaptive ability and so tend to give up the ghost when circumstances change.

Shape-memory alloy
Bentley and his colleague Siavash Haroun Mahdavi borrowed a trick from evolution to allow their robot to adapt to damage. The snakebot is made up of modular vertebral units that snap together to form a snake-like body (see graphic).

Each unit contains three separate muscles running down its length. The muscles are made out of wires of a shape-memory alloy called nitinol, an alloy of nickel and titanium whose crystal structure shrinks when an electric current is applied to it. Usefully, it regains its original shape and length once the current is removed.

To make the snakebot move in a particular direction, a current is applied to certain wires. When the current is removed, the wires spring back and the robot will jump forward.

The software for making a robot wriggle like a snake is fairly straightforward. But ensuring that the snake will keep moving even if a segment is damaged is trickier, and relies on different segments taking over from the damaged ones.

Genetic algorithm
So Bentley and Mahdavi have created a genetic algorithm (GA) a software routine that takes a survival of the fittest approach to produce a system that continually evolves to improve itself.

The program starts off with a population of 20 digital chromosomes, with each consisting of an initially random binary digit that corresponds to a muscle wire where a 1 represents its activation and a 0 its deactivation. Each of these chromosomes forms the basis of a series of movements in the robot.

You end up with a cyclic pattern of muscle activation, says Bentley. Some may result in the robot moving and some will not. The GA tries them all out and awards them a fitness rating, depending on how far it makes the snake move.

The two best chromosomes are then saved, the remainder are mixed up or randomly mutated and the process is repeated. After a number of generations, the amount of improvement finally tends to taper off, says Mahdavi, indicating that the GA has reached a performance plateau.

Once the robot was mobile, the team disabled some of its segments to see if it could adapt to injury. Initially it was immobilised, says Bentley, but as the GA continued to try to improve the locomotion, it gradually worked out how to move again, albeit more awkwardly and with an ungainly, dragging gait but it was still good enough to get the robot to its destination.

[sadik]

A snakebot, also known as snake robot, is a biomorphic hyper-redundant robot that resembles a biological snake. Snake robots come in many shapes and sizes, from the four stories long, earth quake snakebot developed by SINTEF, to a medical snakebot developed at Carnegie Mellon University that is thin enough to maneuver around organs inside a human chest cavity. Though snakebots can vary greatly in size and design, there are two qualities that all snakebots share. First, their small cross section to length ratio allows them to move into, and maneuver through, tight spaces. Second, their ability to change the shape of their body allows them to perform a wide range of behaviours, such as climbing stairs or tree trunks. Additionally, many snake robots are constructed by chaining together a number of independent links. This redundancy makes them resistant to failure, because they can continue to operate even if parts of their body are destroyed. Properties such as high terrainability, redundancy,and the possibility of complete sealing of the body of the robot, make snake robots very interesting for practical applications and hence as a research topic

[sudhir dhadge]

hi im ramya an electronic engineering student im doing paper presentation for snake robot for spying ppt so i need information and help

[necpra]

i need information about snake robot useful for india