Fractal Robots

Introduction

The science of Fractal Robots holds the promise of a technological revolution unlike any other. Fractal Robots are based on a simple idea. Machines that can change shape from one object to another are created by motorizing metal and plastic cube bricks. Suppose you had enough bricks and told the bricks to move around and build a house. It is comparable to children joining Lego bricks to construct a toy bridge. Like playing with Lego bricks, except that we use computers to control the tasks. There is no need for manual intervention. Fractal Robots are computer software’s hardware counterparts.

What are Fractal Robots, and how do they work?

A Fractal is a type of mathematical shape that looks the same and is limitless in complexity. So, its body or form will be the same wherever you look. The Fractal Robot falls under the same definition because it seems identical and can adapt to any shape. Thus, it can have geometric, pattern, or image shapes. For example, it may look like infinite cubes joining together. They have between 1000 and 10,000 atoms wide sizes. It is a powerful concept because you can use these robots to build countless objects. These computer-controlled robots can help in any industry, production units, construction, etc.

What are the mechanism and use of Fractal Robots?

Great effort makes these robots in simple cube shapes. So there are fewer moving parts. You can also produce these in massive numbers. Moreover, these are highly flexible and are made from the cheapest
metal or plastic materials. You can also use any other material like clay or ceramic. Plus, the environment-friendly elements. There are electric contact face plates that use data signals. These robots can join together using 45-degree petals and locking into each other. Using a motor, these can move. In addition, these have RAM, ROM, and an operating system, just like a computer. There are three types of self-repairs these robots can perform. A self-repair is vital for nanorobots or microscopic machines. The robots can also rebuild or resize.

Applications

There are limitless scenarios for these robots, like building bridges, firefighting, entering buildings, defense technology, etc. You can also use these for earthquake applications, medical, space exploration,
and more. Countless uses and create opportunities for using these computer-controlled microscopic robots. For example, it can help operate on shrapnel victims, 100% robotic space exploration. Or enter the human body through tiny blood vessels. It can rebuild itself inside the human and perform delicate surgeries. Another example, you can use these robots to enter earthquake-damaged buildings, clear
rubble, re-construct, etc. The flexibility of resizing, rebuilding, and computer control is useful for limitless scenarios.

What are the limitations?

Although there are no limits to using these highly advanced robots, our tech is still in its infancy. Also, these are expensive to operate, at $1,000 per cube for each 1st generation, then $100 per cube, and so on. It requires special software that must be precise and highly flexible. It takes a lot of work.

Conclusion

This technology is new and has yet to enter the world with a stronger footing. Its at its early stages. So, it may take a while, 4 to 5 years, or more. But when it is experienced and tested, it will quickly become a common practice. It is because the Fractal Robots can perform highly sensitive and demanding tasks. Therefore, it promised to revolutionize our future. Also, it will help to save time, perform complex or impossible tasks, and make it more affordable for us.