Artificial brains can control the robots in future.

 

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Artificial brains can control the robots in future. 

Artificial neurons can be made by using fullerene-onions. 

Fullerene-onion as the artificial neuron In the middle of balls is the atom, where electromagnetic radiation will impact. The internal fullerene ball will be acting as the membrane of the neuron Then the internal fullerenes will affect the outer fullerene ball, which is wired to another system by using carbon-or some other material artificial axons. 

The internal fullerene ball can be equipped with nano springs, what is conducting the electricity to a certain axon. The artificial axons can be the carbon atom chains, which are in the nanotubes. The axon would be connected to the nano-size microchips, where is stored the action, what each signal must do. So this kind of technology can make it possible to make artificial brains for robots. 

There are also made visions where the artificial neurons would be made by using the glass-bottles where is the contact plates inside them. The electricity or the data is connected to the membrane, and then the electricity is connected to the right wire. The routers and switches are making sure that the data is traveling in the right direction. So every single bit line is equipped with the code, which helps the system find the right microchip. 

The recognition number of the data line acts as the telephone number. And it routes the data to the right microchip. If the robot must react to the visual sensation the camera would send the image to a computer or microchip, which will equip the data with the "phone number", which sends it to the microchip, which has the right movement series stored in its memory. Machine learning means that the microchip will send the central processor feedback, what else it would need for making something. Then the central processing unit will include other recognition numbers with similar data. 

In the machine learning procedure, the system will ask what else it should be done, and then the microchips will send the CPU the signal, what kind of actions is stored in their memories. Then the system can make a simulation, what the system will do if the reaction where is included some certain action will be made. And if the action is favorable, the CPU will connect it to the action that is stored in the certain microchip. That means that the system can contain even millions or billions of miniaturized microchips, which have certain actions stored in a database. 

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Fullerene-onion (Image II)

The mercury can use as a neural membrane as well as the nano springs. 

The mercury can replace nano springs. The same way a small drop of mercury can use in this operation. The idea is that the mercury drop will put in the chamber, where it can be connected with the right wire. 

Same way with nano springs the mercury can put in a chamber and it acts as a membrane in the neuron. The mercury can hover in the metal chamber or it can put in the electronic crystals. The magnetic field will deny that thing touch to walls of the chamber at the wrong points. Nanosize routers and switches are connecting those parts. They can operate like some pentodes that can conduct the data to many neurons at the same time.

The ideas of the artificial brains are interesting, and there are made a couple of ideas about that kind of systems. In some systems, the hollow crystals can fill with mercury, and then the change of the form of the mercury will make the connections between the right electric wires. 

The thing in every type of system is that the membrane must not lose its electricity or touch the wall of the chamber too early.  If the membrane touches the chamber, it will be lost its electricity and data. And that makes this thing very hard to make. Maybe this kind of systems is the everyday life in the future