The photonic chips are the new tools for computing.

Things like quantum computers require ultra-fast data handling systems to control them. The quantum computer is the most powerful calculation system in the world. The problem is that the quantum computer requires binary computers to input and output information to the system.  Researchers cannot connect things like screens and keyboards straight to the quantum computer. That's why there is needed a binary computer between the quantum state and input-output devices. 

When the controlling system notices some anomaly it must react immediately. Another thing that the system requires is that. The system that controls the quantum entanglement should not disturb the quantum entanglement and sensors. 

That downloads and uploads data in and out from superpositioned and entangled photons. Or some other particles. All electromagnetic systems cause electromagnetic fields that can affect data that travels in the qubit. 

So the answer is the photonic microchip. The photonic microchip can load data to photons and then deliver it to the quantum computers. There is one little problem with photonic computers. The system needs regular quantum computers to drive information to photonic computers. And, the new nanomaterials can make it possible to change photons to electricity and backward. 

In this model, the quantum computer has three stages. 

The regular binary computer. 

The photonic binary computer

Quantum computer. 

Image 2

The input will happen through the regular binary computer, which decodes it to the photonic binary system. And then the photonic binary system transfers data to the quantum state. When the quantum state makes its duty, the system will return the data to the regular binary computer through a photonic binary computer. 

This model means that the system is scalable and it saves energy. The binary system calls those other layers or states to work with a mission that takes too long time for the first level. If photonic computers cannot solve the problem in a certain time. The system transfers the problem to the quantum state. 

Image 3 

Those photonic processor rings look like token ring architecture. (Image 2)The processing system can involve many processors. That allows it to drive multiple databases at the same time. Or they are hybrid systems. That uses mesh-protocol-based architecture (Image 3). 

In that system, the central processor shares the missions with the other processors. The neural networks use mesh protocol. The mesh- or distributed networks have one benefit to centralized networks. If one processor has problems or damages, the data can pass that processor. 

When we think about the primary computers the photonic microchips can make the ring where they drive information. The system can involve two photonic microchip rings. It can compile the intermission after each processor drive. And if there are anomalies like different results there is something wrong. 

After a certain time. The system can transfer data to the next processor. And when the processor transfers the mission to the new processor. It can make the backup. 

Then there is the control system between those two rings that can compile the data. And that can be the new tool for systems that drive complex data structures. Things like the large language model. The LLM-type systems require. The new physical tools to handle information. New systems must support quantum calculation more effectively. 

The system must start to drive multiple databases at the same time. The photonic systems allow researchers to make new systems. That supports machine learning more effectively than traditional systems. 

https://scitechdaily.com/harnessing-light-quantum-materials-supercharge-data-transmission/

https://scitechdaily.com/integrating-photonics-with-silicon-nanoelectronics-into-chip-designs/

https://scitechdaily.com/microscopic-marvel-a-photonic-device-that-could-change-physics-and-lasers-forever/

The new nanomaterials can make it possible to change photons to electricity and backward.