Photonic computers are a medium between quantum computers and regular computers. In the stages the quantum computing the binary computer inputs data to a photonic computer. Then the system takes photons to frame and starts to make the quantum entanglement. The photonic computer uploads data to photons and then controls the quantum computers.
An ability to make material magnetic using light is important for photonic computers. The photonic system requires some kind of bridge between the photonic system. And regular computers. The data that can be transferred from the photonic chips to regular mass memories must transformed into electric or electromagnetic form. The photonic computer can send data from photonic layers to regular computers using light.
The quantum computers require extremely high accuracy. The system requires exact knowledge of the behavior of the photons that transmit information in the quantum entanglement. This is a problematic thing because the Heisenberg uncertainty principle means that we cannot quantify the precise place and speed of the particle same time. The particle has movement in the visible world.
But when it releases energy, that is stored in it it causes the unseen but existent movement. That means the particle also moves between energy layers. For determining the precise place and speed of particles the system requires an independent measurement system. Each quantity has its own measurement system, and then the support system connects that data.
"Schematic of entangled photons generated in a periodically poled stack of 3R-MoS2 crystals. Credit: Ella Maru Studios" (ScitechDaily, From Spooky Action to Real-World Tech: Columbia’s Quantum Entanglement Breakthrough)
Quantum computers require the ability to react to those changes. That gives very high accuracy but it requires the ability to handle large datasets and react to them immediately. The support systems must have high-power calculating capacity. That they can react the right way.
The fluxonium qubits are things that can make it possible to transmit data in the series. If the system can create multiple qubits very fast, that thing makes it possible to create the error detection for the quantum computers. The difference between answers means that there is an error. Error detection is a key element for error correction.
Long-distance quantum communication requires the ability to transmit qubits through long distances. The problem is how to make the qubit keep its information. MIT's tests with highly accurate qubits can be the answer to that problem. In long-distance quantum communication, the system can pack information into particles like photons or some other piece. Then it shoots that particle through the quantum channel.
The receiving system stops the particle and then transmits information to the receiving particle using superposition and quantum entanglement. That kind of system requires new types of data cables that are more like small nano-technical particle accelerators. The system can shoot the qubit particle through the nanotube. Or make superposition and quantum entanglement through those nanotubes.
Long-distance superposition and quantum entanglement are the things. That is ideal but very hard to make.
Nanotubes inside altermagnetic structures can make it possible to protect qubits over distances. Those systems can protect long and short-distance quantum networks. Short-distance quantum networks can operate using superpositions and quantum entanglements. In longer distances, the system can pack information into qubits that it shoots through the quantum channels.
That means inside houses the data can move through the quantum entanglements and in longer distances the system can transport data in the form of a single particle.
And maybe in the future data travels in nano-size particle accelerators in the form of long-distance quantum entanglement and superposition or in individual particles turned to qubits. Similar systems can transport qubits over long distances. The system can load data to the particle that is in the frame using quantum entanglement. Then that system can shoot the qubit forward.
https://scitechdaily.com/100x-faster-light-powered-memory-thats-revolutionizing-computing/
https://scitechdaily.com/breaking-quantum-limits-mits-fluxonium-qubits-achieve-unprecedented-precision/
https://scitechdaily.com/from-spooky-action-to-real-world-tech-columbias-quantum-entanglement-breakthrough/
https://scitechdaily.com/how-beach-waves-illustrate-heisenbergs-uncertainty-principle/
https://scitechdaily.com/mit-scientists-just-made-a-material-magnetic-using-light/
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