What makes a neurocomputer different than a quantum computer?

What makes a neurocomputer different than a quantum computer?

Diagram 1: The difference in computing between the neuro-and quantum computer.

1) Main data handling unit

2) Data flow

3) Third part of the system, what is selecting the best solution by using the data, what is preprocessed in the main data handling unit.

Upper image: Quantum computer uses the linear data handling process, in multiple lines. That makes it more effective than a neurocomputer if the mission requires fast actions.

Downed image: Data jumps between the data handling layers in a neuro computer, which makes it a little bit slower. But the ability to handle data in two or more lines makes the system more diverse than some quantum computer.

The system connects the data from the memory blocks in that data, which gives it the ability to modify the data. The third part of the computer is the unit that selects, which solution is better if the two main data handling units have a different solution.

This is the role of the cerebellum in the human nervous system. In some visions, the cerebellum can replace by using a microchip, if there is some kind of tumor. The third part of the neural system must not very powerful, because it handles preprocessed data.

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Diagram 2: The simple model of artificial neurons

1) Microchip

2) Nano spring

3) Artificial axon

When the microchip detects the signal, what comes from an artificial axon it would launch the nanospring to make the connection. In some other visions, the nanosprings, what are the spiral molecules, what mission is to close the circuit would be on the layer, and when the electric impulse comes from the axon it would launch the nanosprings to make the connection.

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What makes a neurocomputer different than a quantum computer?

The difference between neuro- and the quantum computer is that the data travels in a quantum computer in one direction. The neurocomputer data is jumping between the data handling layers, and this is the thing, that makes the neurocomputer able to think. The thinking process is the ability to connect the data that comes from the sensors with data that is coming from the memory units. So the thing, that makes human brains so powerful tool is that they are handling the data in multiple centers and multiple layers.

But the thing is that human brains are not a quantum computer, but they are either the neurocomputer. They are a hybrid tool, which means the data handling layers of the neurocomputer is created by using quantum technology. So why cannot create artificial brains? The reason is that the needed connections between neurons are possible to make, but there are billions of more connections in human brains than there are stars in a milky way.

Nanotechnology would allow making artificial neurons. In the artificial neurons, the nanosprings or spiral carbon molecules would conduct the electricity to the wires, which are acting as artificial axons. The artificial axon might have two states. The quantum state, what requires the temperature of zero kelvin. And the "hot state", where the electricity can travel by wires or by laser rays.

But if we can make artificial neurons, maybe someday, we can create synthetic brains. In neurons in the layer, that is sharing the data to axons. And there is a possibility that the neurons can be created by using the small-size plastic bottles, where is the microchip-controlled silicone layer inside it. The idea is that the layer or nanosprings of the outer layer of it would make similar electric connections to the wires what natural neurons are making.

The human brains are like a quantum computer that handles the data in multiple layers, and the number of connections between the neurons is making human brains more powerful tools than any normal computer can be. In human brains, every neuron is the data handling center, and when the data comes from sensors, the brains are starting immediately to find the action which is connected with a certain signal, and during this process, the data travels through billions of neurons. In this process, the brains are acting like a quantum computer that has qubit with billions of layers.

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