The sliding or uncertain protocol in the microprocessor can be the next-generation computer system.

    

The sliding or uncertain protocol in the microprocessor can be the next-generation computer system. 

We can call this as the limit-computer because the voltage can go near zero but it ever reaches it. The idea is the same with a limit in mathematics where the curve closes the value but ever reaches it. 

Even binary computer systems, what are using standard binary mathematics where bits have values zero and one can be fast. If bits are described like this (0<X=0) and (X<Y=1), the speed of the computer would be rise to a higher level. Because in that system is no need for a clock that tells that if the electricity is cut. The necessary thing is to keep the voltage at the minimum level all the time. So, in this case, the level of electricity is never zero. But the level of voltage that is below some layer like 300 volts is described as zero. 

The idea of the quantum computer is extremely simple. The simplest possibility of the quantum system is the voltage meter that is connected to the electric wire, and theoretically, we could build the quantum computer, which bases the voltage meter. But could this system work? 

The thing is that the sliding version of a regular 0 and 1 type binary processor can be made by using the voltage meter, but that sliding system requires more powerful electricity than a regular microprocessor. The secret of the sliding mode of the microprocessor is the system uses the uncertain descriptions of the zero and one. That means that (0<X=0) and (X<Y=1) In the next example (X<300=0) and the (300<Y=1). The level of electricity is ever zero, but the value group between one and 300 is translated as zero. 

That means that all values as an example between zero and 300 are described or translated as zero. And values that are above the 300 are described as one in the kernel of the system. So how the qubit version of this system would work. The thing is that the system requires two power lines, where the bit line is shared in pairs, and the system uses four layers in this case. There could be a third wire, what tells the system is the power on or off. In this case, the levels of a qubit are three, but the high-speed data transmission would make the system very fast. 

In this case, the 0 and one are the binary values, which are acting like normal bytes. The idea is that the electricity or level of voltage, which gives values 1 and two are not sharply described. And the uncertainty gives the speed of that system. Maybe someday, this kind of system is the base, to quantum computers, what are operating at room temperature. The problem is that the system requires very high voltage, and that means that it will be extremely large, which means the size of the small city. Or it requires the superconduction and extremely low temperature. Also in this case the size of the computer would be the factory. 

So is the "zero wire" the wire what tells is the power on or is it off give one layer to qubit? So the three-wire qubit has three or four layers depending on the way how to calculate those layers.