The quantum computer simulation (Part II) and neurocomputer

The quantum computer simulation (Part II)  and neurocomputer

Passing connection for microprocessors 

1) Zero wire for values 0 and 1

2) Microprocessor for values 2 and 3

What if we pass the microprocessor with a separated wire. That tells when the power is on and when it's off. 

One simulation type for the quantum computer must be mention, and that thing is what if the computer manufacturers would make the zero-one wire that goes outside the microprocessor. That thing would allow the values of the processor would rise to the four-layer qubit. Let me explain why this thing would happen. The normal computer and microprocessors have two bits (0 and 1), which means that the processor has two layers 0 and 1. This kind of structure is easy to make by using 2-dimensional architecture. In this traditional microprocessor architecture, the idea is that the data travels in one layer structure. 

The components are put on a layer. When the electricity is cut from the wire, the value of the processor is 0. And when the electricity is on, that gives a value 1. The problem is how the computer separates the value zero from the situation where the electricity is cut. In a modern computer, the system uses a clock, and when the electricity is cut at a certain time, the system translates it cutting the electricity. 

But if we want to make the processor what has a four-layer qubit (0,1,2,3) we can simply pass the processor with the simple wire, which is reserved for values 0 and 1. Those values are telling that the electricity is off (Value 0) and on (Value 1). Then the processor itself has been reserved for data handling. The values 2 and 3 left for computing, and that kind of thing could rise the power of the calculation. 

The diagram of neurocomputer

1) The main data-handling units

2) Data what travels between the units

3) The "judge" the part of what mission is to select the best solution, what the main data handling units are making. The mission of that unit is the same as the cerebellum in the human brains. 

The neurocomputer

In neural microprocessors or neurocomputers, the data travels in two layers, where is the middle layer, which would transmit the data between those layers. And there is needed the swap-processor, which would control the action of those processor layers. The swap processor is needed when the processors are using the same resource. In that case, the swap processor would give the turns for those processor layers. 

So the data travels between those layers as it travels in human brains. The fact is that the layers of the processors can be computers. And that makes it possible to connect the quantum computer with a neurocomputer. So those processor layers can create by using quantum computer technology, which makes this kind of system even more powerful than human brains. The reason why neurocomputers are not so fast as quantum computers are that the data is jumping between the layers of the processors. 

And that means that the neurocomputer processes data for a while before it would make the decision. The thinking process of the neurocomputer would be that the processors are connecting more elements with the data, what is jumping between those layers. And the third computing element will choose the most effective things from the data flow, which travels between those main layers. The main layers of the neurocomputer can be quantum computers, but the third part can be a less powerful processor. And its mission is to act like the cerebellum in the human brains. 

The neurocomputer is the computer that can think and learn independently. The structure of that system would make it able to think like a human, but the problem is that the neurocomputer is a little bit slower than its cousin quantum computer. But what if we would combine quantum computer and neurocomputer? The fact is that the layers of the neurocomputer can also make by using quantum computers. So that thing is one of the most interesting things in computing.