A natural quation, does the vacuum encoder sample in phase between samples? In this model direction is phase alignment, distance is quantization levels per sample. Wave propagation causes phase alignment along the direction of propagation. OK, but what is the static gravitational field? Likely that is caused by the occasional, and rare magnetic quantization which stabilizes phase a bit along the gravitional field. That is why mass attracts, they tend to flow along the phase aligned field, and that is why waves curve slightly, it is affected by the minute phase alignment along the gravitational field. The universe is not completely encoded, that is why we have simultaneity. Thus the occasional nuclear emission and the occasional magnetic quantization. Then the large static fields and the occasional nuclear emissions are the side lobes of an incomplete encoding of our world, the vacuum is still trying to complete the incomplete standard model. What if our region never quantizes a magnetic disturbance? The gravitational field become phase random, increasing the probability of a magnetic field quantization, hence the system restored. So, I guess, quantization levels are eliminated when phase become random.
In the end, the vacuum completes the encoding, swapping waves with the various regions until everything is compact to the highest rank necessary. The universe is cold and dark, but the disturbance completely quantized, the final uncertainty constant established, and the standard model complete. We might think of the vacuum encoder as trying to eliminate wave propogation entirely. Phase alignment would be quantized.
What did the original disturbance look like? Unquantized random vibrations of th Higgs field. Where did it come from? I have no idea. What made the vacuum have this property? I have no idea.
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