Universal principle of dilatation
Dilatation is a fraction of time in which light moves over gravitational fraction of space.
Dilatation is like a snapshot on a camera. The smaller the exposition (gravitation) the tinier fraction of space-time gets captured. Since measured speed (speed of light) reminds the same, in les intense gravitational fields, capture of space-time-speed gets more refined. The consequence of that time flaw increase is contraction of space and vice versa. In more intense gravitational fields, dilation increase (flow of time slows down), and since measured light speed stays unchanged, the space gets bigger.
Measured from our RF, dilatation determines the occurrence of observed space-times in our space-time. Les intense gravitational fields have smaller dilatation so their frequency increase. Bigger dilatations manifest as lesser frequency.
In first scenario, where bigger frequency means bigger occurrence in our dilatation, compared to those RFs, our slower snapshot captures more of their space-time. It is perceived as blue spectra which appeares from black, and moves towards red. As measured dilatation increases, it is the same as if our RF snapshot gets relatively shorter. Occurrence of more intense dilatational fields, which manifest as lesser frequency, in our space-time decreases. The spectra moves towards red and disappears in black (fig. 01).
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fig. 01
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Dilatation measured for acceleration space fraction is acceleration dilatation “da” and gravitational dilatation “dg” is a value for one light second space-time region.
For both cases applies the equivalence;
Gravitational dilatation for celestial body light second space fraction equals to a square root of its margin space markers acceleration dilatation product.
where “da1” represents acceleration dilatation on surface, and “da2” stands for acceleration dilatation at one light second distance space fraction.
In further reading the gravitational dilatation would be denoted as “d”.
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