Another writing about qubits

Another writing about qubits

This writing could also be named as the "three electron problem", but the thing is that we have thought the qubit as the molecule, which would touch the frames of the gate. And as I have written before, the number of touches would mean a certain level or value of qubit. This is one way to think about the problem. But there is a couple of other ways to closing this kind of problem.

One of them is just using the modified tunnel microscope for making the qubit. The thing is that the scanning tunnel microscope is the stylus, which would hang ion or electron on the surface of the metering particle. So if we would create the transmitter, what would use multiple stylus or antenna, what would send multiple electrons at the same time, and that system would create the necessary value for the qubit.

And those antennas would target the gate, which might have very many frames. That allows the system to give qubit as many values, what the creator of the system wants. But of course, we would need to make very much work with this kind of thing, before the first fully functioning quantum computer would be possible to create.

But let's continue to think about the qubits. The thing is that the problem of the qubits can be solved in other ways, which might seem very different than using the normal cable, where those bits would travel in lines, which would make those computers more effective than any existing computer. And one of those possibilities for solving that kind of problem can be mentioned here.

The solution for creating the qubit could be the magnetic version of the bubble, which is filled with balls. In this case, the ball would be filled with electrons or ions. The value of the qubit would define by the electrodes, where the ions or electrons will touch.

So, in this case, the magnets would hover those particles, and the ball would be covered by electrodes, what would create the form, what looks like little bit longitudes of the map ball. This kind of system would look like miniaturized- or nano-sized map ball, and the use of nanotechnology or nano-sized mosaic on the structure of that ball would make this thing true.

This would be the so-called "stable solution" for qubits. The movement of those particles would be extremely short. And the problem is how to adjust the track of each particle. Of course, adjusting the track is not enough, and those particles must be controlled during their journey to electrodes.

The purpose of this kind of action would deny the possibility, that all of those electrons or particles are touching the same electrode. But even if the system would become operational there is much work left in the operating systems and programs. And at the beginning, the quantum computer would be the hybrid solution, where another traditional computer would be used to code commands to the quantum computer, which could return the answer thought the regular computer.

If this is the mode of the system, that thing would be used to solve extremely long calculations. That hybrid solution would be slower than a pure quantum computer. The thing would operate that when the calculation would input to the quantum computer by using the regular system, that calculation is away from the hands of the operator until the quantum system will return it. And that kind of system is unstable if the normal rules of computing would consider quantum computers.