Universal principle of spectrum
The principle of light speed
determines the RF perception speed limit. In measured RF, different gravitation and gravitational dilatation values result with different wavelengths, while their speed remains unchanged.
In relation to RF from which we perform measuring, for les intense gravitational regions, the consequence of slower light speed is a shift towards blue area of spectrum, while the consequence of faster light speed for more intense gravitational fields results with shift towards red (fig. 01).
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fig. 01
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Perceivable spectrum is therefore space-time stretch between black and black caused by speed. In our frame of reference, the manifestation of different speeds are bigger or smaller occurrence of waves. Faster speed would register as longer wave sequence and slower as shorter.
Therefore, wavelengths “λ” are manifestations of dilations so we can write equivalence;
since dilation of time equals dilation of space
i.e. one second and one meter change for dilatational amount, comes forth that it is the same if we describe “λ” as the wave time rather than a wave length since both are the consequence of space-time stretchiness. Besides, the word “length” is often used in describing time interval (How long did something last).
Knowing that product of wavetime and frequency “f” results with light speed;
i.e.
comes forth that frequency equals to a light speed divided by dilatation as well as to gravitation divided by power of corresponding dilatation;
To determine frequency in dilatational time fraction (not in one second time fraction), we write the equivalence
Where "fs" stands for frequency measured in one second and 1/d is one second and dilatational time fraction difference. From there, it comes forth that frequency value measured for its corresponding dilatational time fraction equals to a speed of light;
Therefore, we can describe frequency as space upon time, rather than space upon power of time. The result of that frequency multiplied with its wavelength is gravitational space fraction.
From equation above "f" would always measure as a constant value. So what determines the constancy of our perception is the frequency of our universal time in our universal space. In other words, frequency is the occurrence of wave time in gravitational space fraction. Time and space stretch for the same amount, but their relation, the frequency, remains unchanged.
According to that, the region of visible spectrum is determined by gravitation and gravitational dilatation or wave length time. Since the visible spectrum is a part of infinite spectrum, its perceivable area is determined by gravitation and gravitational dilatation of RF from which we perform measuring.
Acceleration result for Sun’s surface given by
is 636 m (which is the amount for light speed difference expressed in meters)
(Newton’s formula acceleration result equals to one calculated throug speed of light and dilatation if calculating Sun’s Schwarcshild radius with corrected Sun’s mass and corresponding Sun’s gravitational variable G)
Gravitational dilation for Earth’s (circa 0,0000000007) is also a dilation for light second space fraction which according to equation
match to average gravitation of corresponding light second (circa 0,208 m).
Including measured acceleration (9,807 m) in equivalent equation for acceleration dilatation,
comes forth that gravitational dilation on Earth’s surface (in gravitational space fraction) amounts circa 0,0000000327s which belongs to NUV (Near Ultra Violet) spectral region.
The dilatational value for Sun’s surface light second region is about 0,00000212 s. It is a fraction of time in which light travels corresponding gravitational space fraction (636,249 m).
Induced dilation corresponds to a NIR (Near Infra Red) wavelength.
Visible spectrum on planet Earth is located between NUV and NIR. (fig.)
It comes forth that visible spectrum is the dilatational difference, which means energy manifestation between Sun’s and Earth’s space-time. It also implies that rainbow is in fact a gravitational phenomenon.
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