The father of teleportation is considered to be prof. Dimitri Sedvan. This outstanding mathematician and astrophysicist was born in 2011 in Kyiv. From an early age was interested in issues related to hyperspace and teleportation. At the age of 24, he received a McArthur scholarship, which opened his way to a long scientific career. Over the years, he developed a theoretical solution enabling immediate transfer of three-dimensional objects in a five-dimensional pseudo-Riemann space. For his achievement he received Fields Medal. The next 20 years of research and experimentation resulted in a prototype teleporter that could teleport an object with a diameter of up to 4 mm over a distance of up to 200 km.
The prototype device was dubbed by the team – Perez Portal, in honor of Gil Perez, who was a Spanish soldier who, according to legend, was the first to teleport. In 1593, in unexplained circumstances, he moved from Manila in the Philippines to New Spain in Mexico. This name quickly became popular among Sedvan’s team.
The Nobel Prize, received in 2049, did not suppress the enthusiasm of Dimitri, who, with the support of many countries, could continue his research with access to a multi-billion scientific budget. The money invested and the time spent by Sedvan’s team led to the first successful teleportation of a living organism over a distance of over 2 000 km. This was accomplished in 2057, teleporting Vasil’s rat between Oxford and Kiev.
The teleportation device has been called the Sedvan Sphere. The teleportation itself was dubbed simply – shift.
Teleportation dimensions
Dimitri SedvanImagine abstract two-dimensional beings, so-called Flatlanders. They only see 2 dimensions – length and width (X and Y). They are unable to understand the concept of height (Z) that they have never seen or experienced. They could live, for example, on a sheet of paper. If we would pierce this piece of paper with a pen, in the world of Flatnalders suddenly, out of nowhere, a circle-shaped object would appear – they would only see a 2-dimensional cross-section of a pen, i.e. a 3-dimensional object. By moving the pen up and down, we would make Flatnanders astonished, because in their world this strange circle would increase and decrease. They couldn’t explain it using their perceptions.
Additionally, if we grabbed and lifted their two-dimensional house, it would simply disappear in their world. If we then put the house back on a piece of paper, it would suddenly appear for coaters. Flatlanders would experience teleportation.
Imagine now less abstract three-dimensional beings. They see only 3 dimensions – length, width and depth (X, Y and Z). They can’t see the fourth dimension. If a four-dimensional being would put a four-dimensional object into our space, slowly move it to finally remove it from our space, it would suddenly appear to us, then change shapes to disappear.
This analogy can be extended for subsequent dimensions.And now let’s return to the concept of Flatlanders and their life on a piece of paper. If we fold this paper in half and make a hole in it, flat creatures will be able to immediately pass through this hole to a place that is very distant in their 2-dimensional world.
With this analogy, you can try to imagine the fourth and fifth spatial dimension that we use to travel during teleportation. Teleporters produce an intersection in all five dimensions, through which objects are moved from one point of three-dimensional space to another. That’s what we call a shift.
Sedvan Sphere produces two spheres for a few milliseconds. During this time, matter in the first sphere is transferred to matter in the second and vice versa. The process is accompanied by a short, quiet sound. For a person, everything happens in the blink of an eye, like taking a picture. So it is not possible for a man to put a hand in a teleporter and watch it coming out of a second teleporter.
The technology used the Riemann Cut phenomenon of generating a hyperspace hole in the basic three dimensions. This hole enabled the immediate transfer of matter from one point of three-dimensional space to another, using the fourth and fifth spatial dimensions.
The energy demand of the Sedvan Sphere is growing exponentially, depending on the size of the shifting object, the distance between teleporters and, above all, the duration of the connection. Therefore, it was considered that the time would be reduced to an absolute minimum and a few milliseconds proved sufficient to send the entire material object.
Teleporters are divided into short-range devices (up to several hundred meters), planetary (up to several thousand kilometers) and interplanetary.
There are 5 classes of teleporters, characterized by the maximum size of shifted objects.
Although the weight and shape of the teleported object did not matter, special vehicles dedicated to teleportation were prepared.
In addition to teleportation between Sedvan Spheres, there is the possibility of a one-sided shift. It consists of teleporting an object from the teleporter to the indicated coordinates, i.e. to a place without a teleporter. However, this operation carries the risk of inaccurate spawn at the destination. The greater the distance, the greater the inaccuracy. No one can give exact parameters, but Dominica Lorana, technical director of ISHA’s 2 testing wing, estimated them to a large extent.
Scatter – accuracy of unilateral teleporters
Dominica Lorana
2075-05-22, ISHA HQ, Verdenea
Even the smallest one-sided shift distance is burdened with inaccuracies of several meters. We call this scatter. At a distance of more than 500 km, the spread is several meters. Above the threshold of 3 astronomical units*, the dispersion increases to several hundred meters. For a distance greater than 10 light years, the dispersion is several dozen kilometers. Therefore, people are not teleported to the surfaces of the planets at such distances, but to orbits. Shifting over a distance of more than 1,000 light years has a spread of more than 100,000 km, which is why such teleportations with people have never been tried.
The above calculations are the result of several thousand class 3 teleporter experiments and are statistically correct, but there are exceptions to them. To this day, we are unable to list all the factors affecting the accuracy of shift. Therefore, we must always remember about the risk of unilateral teleportation.
* Astronomical unit (AU) is a distance unit equal to 149 600 000 km (average distance of the Earth from the Sun). The light year is 63 240 AU long.
Devices for direct teleportation (between two Sedvan Spheres) are structurally different from unilateral teleporters and cannot be used interchangeably.
Due to the above limitation, to enable efficient communication between distant planets, you must first teleport a construction team into orbit, which will descend to the planet and install the Sedvana Sphere there.
Shifting technology is as revolutionary as it is unexplored. Unfortunately, teleportation (especially one-sided) has some risks. Its probability is negligible, but there is no guarantee that it will not occur. In the history of Sedvan’s Spheres, three types of aberrations were noted that affected the shape of teleported objects.
