One of the most interesting things about quantum computers is this. Quantum processors can be photon clouds or laser rays. Laser systems adjust photons to a certain energy level.
And the certain energy level is the certain state of the qubit. That makes it possible that qubits have multiple values.
Binary computers have two states zero and one. Because the computer must recognize that the system has switched off. That thing makes them slow.
Quantum computers can have billions of states. The quantum computer's power is based on the idea. Where the data hovers above zero. In binary computers zero means that the electricity is cut.
In quantum systems, zero means the same thing. But the difference is that the zero is separated from the other system. And that means that the system detects far easier if the electricity is cut.
The quantum computer system is based on a simple idea. Data or information can travel in the system in lines, not in rows.
The system makes that thing by using the simple-looking idea that photons can be superpositioned and entangled. And that thing can drive information in lines through the quantum system.
The system shots those energy rays through the hologram. The sensors are observing the brightness of the hologram. Or energy layers in this photon cloud. And each energy layer is a certain state of the qubit. The thing is that photon-based quantum computers are powerful tools.
But those systems require adjustment very often. Those systems are also sensitive to electromagnetic radiation and outcoming electromagnetic effects. So they must be protected against the electromagnetic effect. The laser ray that transmits data to the hologram or photon cloud can travel inside the optic fiber.
There is the possibility that the Earth's orbiter or very far away in the solar system would send the quantum computer or data satellites. The system can stay behind the solar shield. And then it can make many missions. Each of those satellites can be its independent quantum system. And the ground station or some support satellite can be the swapper system. When the quantum entanglement starts to unravel the swapper system would transfer information to another quantum system.
Image 2: The model of the swapper-based quantum computer
1) Quantum system number 1 (one)
2) Quantum system number 2 (two)
3) Swapper system
4) Data flow
When the swapper system recognizes the quantum adjustment in the quantum system one starts to unravel. It transmits information to quantum system number two. And when that quantum entanglement starts to unravel.
The system sends information back to quantum system number one. Another quantum system can continue to work from the point, where the first system ends its job. That system could make long-term calculations without breaks. And that makes it an extremely powerful tool.
The main problem with quantum computers is that they can keep their photons superpositioned and entangled only for a couple of minutes. Then the superposition will be cut, and the machine must re-adjust. That means the quantum computer must store the information before the entanglement ends. Then the quantum computer must re-adjust, and memristors are the components that can help to reach the quantum computer's last settings. Then the intermediate result will be driven to the quantum computer.
And it can continue calculations from the point where it ended its mission. In that system, the quantum computer would send the intermediate results non-stop to the intermediate storage so that the quantum computer can continue its mission.
But then we must realize that there is another way to solve that problem. The system can use two quantum computers. Or two quantum cores for making the system for long-term computing. The thing goes like in the two-server models where the swapper server switches to the operational server when the error level rises.
In that two-core quantum system, the system would adjust the quantum computers in turn. And that allows the system to work without breaks. When another quantum system will lose its quantum entanglement. Another quantum system will adjust. And then, the first system drives information to that second system. Then the second system returns that processed information to the first quantum system.
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