Measure time in trillions of billionths of a second.

 It's time for quantum cryptography. 

Zeptosecond is trillions of billionths of a second. And the new atom clock or measurement method makes it possible to measure time in zeptoseconds accurately. That kind of accuracy is interesting. Because it allows the creation of new and faster microchip technology.

The binary computer is not dead even if quantum computers are coming. Binary computers are still dominating marketing. And in the future binary computers and binary microchips are still in use at the executive level of computer-controlled technology. 

The model of future computing has two levels. Even if quantum computers are becoming coming more common. The problem with quantum computers is that quantum entanglement is not stable. 

When the quantum entanglement reaches energy stability. That breaks the entanglement. And then, the binary computer must re-adjust the quantum system. 

*The quantum computers. That are in fixed positions. 

*And the binary computers that are working as the brain for robots. 

When remote quantum computers give commands to executive robots. It creates order by analyzing incoming data. Then that system sends operational orders for the executive robot. That robot makes the physical job of a quantum computer. 

This model is in use in modern computing. We don't use supercomputers straight with robots. The highly automatized systems use supercomputers as controllers, but in those cases, the supercomputers send commands to robots through the network. And in that model, the quantum computers are just put in the position of supercomputers. 

The virtualization of quantum computers. 

Binary computers can also operate as virtual quantum computers. In those virtual quantum systems, the system shares information as bites (or segments) to separate binary computers. In that kind of binary system, the binary computer group plays quantum computers. 

The TCP/IP protocol makes it possible to share information with segments. And those segments will send to binary computers as a line. That kind of system is less powerful than real quantum computers. But they are more powerful than regular stand-alone binary computers. 

In quantum communication the system shares message to different frequencies. And then that kind of system is harder to break. The thing is that receiver must get all parts of the message. And if there are multiple holes in the information. 

That causes the attacker cannot to read the message itself if that attacker doesn't have all of those frequencies. And because the system will pack information before it sends it. An attacker must also know the precise time. When the system sends the package. If the attacker misses the time, that means the attacker misses the code. 

The term non-symmetrical quantum encryption process means that. The system sends information packages by using separate frequencies and separately adjusted moments. That will physically protect information. 

This system is similar to the container. The idea is that each data pack has an ID number that tells where they belong. The model for that kind of cryptography is taken from warehouses. The idea is that system packs data in multiple packages that must be put in the same place. 

This kind of non-synchronized protocol means that there is a code in each data pack. That code tells the container where the system must drive each data pack. And the thing is that those data packs can send in at different times. They can send from different places. And different times. The idea is similar to the post office. 

The receiving system sends the time when the data packages that belong to certain messages must send. And then it gives the container number. That is the PO box that the system must use. That number that can be as an example 136 tells that the packages that have this registration number must send in, let's say at 8:36 o'clock in Eastern Pacific standard time. Or the time can be Timbuktu standard time. 

The receiving system collects those data packages to container number 136. In real life, those containers can have millions of numbers and letters in their serial numbers. There are hundreds of variants of that model. 

https://scitechdaily.com/zeptosecond-resolution-measuring-times-in-trillionths-of-a-billionth-of-a-second/

See also TCP/IP