Principles of FTL - Lehrfilm 01

Summary

Faster-Than-Light communication, sensors, and travel all rely on “elusive-spatial cosmic cells”; basically, bubbles of space that exist in multiple places at once, as does everything inside of them.

FTL travel works by bursting the bubble, forcing everything inside to exist in a determined location that is different from the one it was burst from.

FTL communications and sensors create resonances without bursting a bubble to send information to- or receive information from its every potential location.

There are three caveats:

• 1.      Bubbles and their potential locations cannot be created artificially. If you want to go somewhere where no bubble has its potential location, you can’t.

• 2.      Calculating potential locations of bubbles from scratch requires more processing power than most vessels can afford. Instead, they use pre-made flight plans and the help of external installations doing calculations for them.

• 3.      Bursting and resonating bubbles requires an extremely volatile and rare particle. The amount a vessel can carry, and therefore the number of jumps it can make, is severely limited.

Full Transcript

Opening

Since the beginning of time, humankind questioned the fundamental nature of the universe.

Today, our growing understanding of cosmic laws grants us the ability to perpetuate our revolution and lets civilization thrive on worlds beyond our own.

This film is a summary introduction to the astro-physical mechanics governing our long march to the stars. 

Title

The Cosmo-Cellular Model of Elusive Space, Eulenkampfsche Corpuscles, and Interstellar Transportation

Slide 1

 The universe, as we understand it today, exists on a spatial-elusive foam structure of cosmic cells.

Slide 2

These Cosmic cells are entangled in pairs or clusters across distances ranging from the microscopic to interstellar dimensions.

Slide 3

The elusive-spatial foam is all-encompassing, but agnostic to baryonic matter. 

Within the entanglement of a cosmo-cellular pair or cluster, all energy and matter contained in one cell have equal potential to exist in every other cell of the same.

The location and composition of cosmic cell contents are consequently indeterminate.

Slide 4

Near the center of gravity-wells, cosmic cells and their entanglements shrink relative to the massive object.

(It is speculated gravitational trace effects through entangled clusters are key factors in dark matter phenomena)

Slide 5

The materiality of elusive-spatial foam is proven by the Eulenkampfsche Corpuscle, the sole particle known to affect its structure.

Slide 6

Directed at the cosmo-cellular wall, corpuscles create a resonance, the inward echo of which is reabsorbed and transmitted throughout the entanglement.

In crossing the cosmic cell interior, the echo picks up traces of the

Material compositionenergetic conditionsgravitic influencesrelative distance and direction

from all cells of the entangled pair or cluster.

Slide 7

This information allows for the detailed mapping of entanglement clusters in real space.

(This is the basis for superluminal echolocation)

(encoded corpuscle signals and echoes are used to facilitate superluminal communication bursts)

Slide 8

A sufficiently strong corpuscle emission bursts the cosmic cell and thereby collapses the entangled pair or cluster.

Entanglement collapse resolves its indetermination of its contents towards a definite position.

Slide 9

Calculating strength and direction of the corpuscle emission allows for the pre-determination of the definite position outcome.

This allows spacecraft to collapse a cosmic cell cluster from one end, while having the final position resolve towards the far side of the entanglement.

In effect, the craft has changed position across long distances near-zero time.

Slide 10

Two limiting factors are prominent in the technological application of these principles:

The availability and support of sufficient processing power to effectively calculate possible definite position outcomes.

(information processing infrastructure)(blind jumps, halfway jumps) 

Sufficient supply of Eulenkampfsche Corpuscles to affect the entanglement structure correctly.

Slide 11

Due to these limitations, spacecraft, especially civilian cargo- and personell-carriers, typically rely on external infrastructure.

Spaceports and deep space stations provide pre-determined flight plans and coordinate large-scale transit-trains to allow for the collapse-transportation of large material quantities.

Military formations and convoys utilize specialized carrier- and satellite-vessels to remain mobile and operational outside of developed space.

Slide 12

Part 8 of this introductory series will showcase the here presented principles using the practical example of deep-space sonar.