Why is the universe there?
by Henryk Szubinski
by Henryk Szubinski
As the observer approaches the object light, the result is that they grow by way of the red shift, but also as the distance between them decreases as the blue shift approaches, the limit as unshifted into folding of the distance between them and the beginnings of the new dimension begins to define the creation of the area of the rectangle that defines the displacement. This rectangle is the area of the second dimension and as you approach so close to the object light, you will start to observe it's inner light. As such this inner volume is the 3'rd dimension and it defines the limit of the rectangle as being pushed into the new volume so that it stretches out around the light object.
from
Wikipedia
date 2019
march 5
In mathematics and physical science, spherical harmonics are special functions defined on the surface of a sphere. They are often employed in solving partial differential equations that commonly occur in science. The spherical harmonics are a complete set of orthogonal functions on the sphere, and thus may be used to represent functions defined on the surface of a sphere, just as circular functions (sines and cosines) are used to represent functions on a circle via Fourier series. Like the sines and cosines in Fourier series, the spherical harmonics may be organized by (spatial) angular frequency, as seen in the rows of functions in the illustration on the right. Further, spherical harmonics are basis functions for SO(3), the group of rotations in three dimensions, and thus play a central role in the group theoretic discussion of SO(3).
Wikipedia
date 2019
march 5
In mathematics and physical science, spherical harmonics are special functions defined on the surface of a sphere. They are often employed in solving partial differential equations that commonly occur in science. The spherical harmonics are a complete set of orthogonal functions on the sphere, and thus may be used to represent functions defined on the surface of a sphere, just as circular functions (sines and cosines) are used to represent functions on a circle via Fourier series. Like the sines and cosines in Fourier series, the spherical harmonics may be organized by (spatial) angular frequency, as seen in the rows of functions in the illustration on the right. Further, spherical harmonics are basis functions for SO(3), the group of rotations in three dimensions, and thus play a central role in the group theoretic discussion of SO(3).
spherical harmonics may be the definition of the ways that the 3rd dimension is made from the rectangle morphing around it by way of the above stages of the rectangle in the space that defines the 4th dimension of the sphere wherein everything is different. There is no longer any balance of approaches made by the observer as +-.
rather everything is "non computable" in terms of the "unpredictability", of there being only space in this inner volume inside the spherical harmonics as types of space ,or as how space is made from the rectangular construct.
So then there is no energy in this volume of space, rather the total of energy is "used up" in the way that the rectangular 2 dimensional space is made into the 3 dimensional surround of the spherical total.
By being able to reverse the way, it would be possible to reduce space to become the alterations of the rectangular area and possible displacements through space in negative time to exit the functions and become the 2 dimensional to the 1 dimensional light object.The 1 and 2 and 3 dimensions being ="reverse group theories".
The spherical harmonics are still in the 2 dimensional rectangle of the positions they are placed in to show their existence.And even is you leave the Earth or larger universe space,you will still be relating to the inner volume of space as used up ,in reference to the amounts of energy on it's outer surface as;
some background data from Wikipedia.
from Wikipedia
date 2019
5th March.
A blueshift is any decrease in wavelength, with a corresponding increase in frequency, of an electromagnetic wave; the opposite effect is referred to as redshift. In visible light, this shifts the color from the red end of the spectrum to the blue end.
Doppler blueshift[edit]
Doppler redshift and blueshiftDoppler blueshift is caused by movement of a source towards the observer. The term applies to any decrease in wavelength and increase in frequency caused by relative motion, even outside the visible spectrum. Only objects moving at near-relativistic speeds toward the observer are noticeably bluer to the naked eye, but the wavelength of any reflected or emitted photon or other particle is shortened in the direction of travel.[1]
Doppler blueshift is used in astronomy to determine relative motion:
from Wikipedia
date 2019
5th March.
A blueshift is any decrease in wavelength, with a corresponding increase in frequency, of an electromagnetic wave; the opposite effect is referred to as redshift. In visible light, this shifts the color from the red end of the spectrum to the blue end.
Doppler blueshift[edit]
Doppler redshift and blueshiftDoppler blueshift is caused by movement of a source towards the observer. The term applies to any decrease in wavelength and increase in frequency caused by relative motion, even outside the visible spectrum. Only objects moving at near-relativistic speeds toward the observer are noticeably bluer to the naked eye, but the wavelength of any reflected or emitted photon or other particle is shortened in the direction of travel.[1]
Doppler blueshift is used in astronomy to determine relative motion:
- The Andromeda Galaxy is moving toward our own Milky Way galaxy within the Local Group; thus, when observed from Earth, its light is undergoing a blueshift.
- Components of a binary star system will be blueshifted when moving towards Earth
- When observing spiral galaxies, the side spinning toward us will have a slight blueshift relative to the side spinning away from us (see Tully–Fisher relation).
- Blazars are known to propel relativistic jets toward us, emitting synchrotron radiation and bremsstrahlung that appears blueshifted.
- Nearby stars such as Barnard's Star are moving toward us, resulting in a very small blueshift.
- Doppler blueshift of distant objects with a high z can be subtracted from the much larger cosmological redshift to determine relative motion in the expanding universe.[2]