Real- and virtual quantum computers and Riemann's "Zeta-function".

"Researchers have developed a new error-correction system for quantum computers, using qLDPC codes and reconfigurable atom arrays to reduce the physical qubit requirements, enhancing scalability and efficiency. Credit: SciTechDaily.com" (ScitechDaily, Innovative Error Correction Framework Paves the Way for Scalable Quantum Computers)

Scalable quantum computers are the next-generation tools. But the computer must know all parts of the system. Without complete knowledge of the system and its behavior, the quantum system cannot operate as a trusted system. There are many problems with quantum systems. 

One of the problems is the switch that shares data with the multiple quantum states of the qubit.  The new silicon-based architecture can solve this problem. The switch is the interface, where the binary computer transfers information into the quantum system. 

The quantum computer must have an intelligent operating system. That can predict and control the quantum system. And its interaction with its environment. The main problem in quantum computers is error detection. Only another quantum computer can check the results of the quantum computer's operations. 

When we think about local anomalies the answer for the error detection is to use another quantum computer in some other location. But that cannot solve the global anomalies like FRB hitting the Earth. In that case, the anomaly affects all quantum computers around the world, 

Another thing that causes problems is entropy. Growing entropy in quantum entanglement can cause problems. The entropy in quantum entanglement forms when the elementary particles that the system puts in the superposition and entanglement spin in the quantum field. 

The quantum field is also in the particle's structure. And that causes whirls between superstrings that form the particle. Those whirls send oscillation to the quantum entanglement, and that oscillation causes errors in the data transportation. This thing is like waves. That travels in the string that connects those particles. 

Virtual quantum computers can be answers for problems in quantum systems. The virtual quantum computer is the neural network-based solution that imitates a quantum computer. Each workstation in this system acts like an individual state in qubits. 

"Researchers have made a pivotal advance in quantum technology by developing integrated photonics that enable the control and manipulation of light on silicon chips. This innovation facilitates ultra-secure communications and enhances quantum computing capabilities. Credit: SciTechDaily.com" (ScitechDaily, How Silicon Ring Resonators Are Rewriting the Rules of Quantum Computing)

But while we wait for the quantum computers on our desks. We can use virtual quantum computers. 

In virtual quantum computers the neural network shares the calculations between multiple regular workstations. The best example of that thing is the system, that cuts the DNA into pieces, and then decodes those sequences at the same time in multiple workstations. 

The new DNA analysis systems use a quantum calculation method. The system cuts the DNA into pieces and drives each piece into the analysator. Because, multiple analyzers can operate with the same DNA, that makes the DNA decoding faster than otherwise. 

In quantum calculation, the system shares the problem with multiple workstations. This method is extremely effective when the system operates with things like Riemann's "zeta-function". The system selects the points where it takes prime numbers that "zeta-function" creates. Then that system shares the prime number sequences to the workstations. And every workstation starts to operate with a certain part of the number row. 

In virtual quantum computers, the system can share things like sum, as an example: Riemann's hypothesis between multiple workstations. 

Then the system can start to operate the code-breaking process using certain points of Riemann's hypothesis. In that process, each workstation operates with certain bites of the number line that Riemann's  "Zeta-function"  produces. So in this process, the system shares certain values, that the function gives to the workstations. And in that process, every workstation can operate with as an example 5000 values. 

https://scitechdaily.com/how-silicon-ring-resonators-are-rewriting-the-rules-of-quantum-computing/

https://scitechdaily.com/innovative-error-correction-framework-paves-the-way-for-scalable-quantum-computers/

https://scitechdaily.com/nanoranger-redefines-speed-and-precision-in-genetic-diagnostics/

https://scitechdaily.com/solving-quantum-mysteries-physicists-confirm-entropy-rule-for-entanglement/

https://en.wikipedia.org/wiki/Riemann_hypothesis