The process of communication between our campuses was severely impacted several years ago when locals chose to remove copper wires along the telephone line.
This led our team to begin investigating the use of quantum communications relying on photon entanglement between each terminus.

Prof Heckvinsonn was the head research scientist for the project. Data has been successfully shared between our main sites, at a distance of about 33 Kilometers. The below illustrates the flow and detection of our messages from Sender to the Recipient. It highlights the importance and function of the Comparator.

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We have used the entanglement of light photons to achieve our aims. Due to the incredible abundance of photons in any two places (that number approaching Infinity), it is a simple matter of identifying two photons with the entangled spin, energy level and directional vectoring. These are then considered as “entangled”.

To transmit data between two locations, we then apply a slight change to the photon at the Sender location. This happens simply by detecting and measuring the properties of that source photon, as in doing so it alters that photon.

To then receive the data at the target location, all we need to do is to find a matching photon at that location (again, there will be close to an infinite number at the Recipient location), and so we will have found the subsequently entangled photon. Our data message, using a process similar to the TCP-IP protocol of “sliding-window data transfer”, is then stored within the comparator for validation and interpretation.

A major breakthough in the process was encountered during 2025 and we are presently attempting to patent the processing.

UOMAN.