Archive for the ‘curvature’ Category

Curvature Without a Linear Vector

One latest discovery is that of finding two alternate locations, simultaneously, of a single inline linear vector. Existing between both locations is a single line, without a curve. However, from an exterior boundary of both alternate locations, an unusual curvature was measured. Until now, there has been no way of measuring any kind of curvature near the exterior vector space. The recent extrapolation and composition of particulate measurements only allows one conclusion: curvature may exist independent of alternate locations of vectors!

Although simpler methods of measurement exist, none will be as accurate as those used when doing particulate measurements. (How else can one find the aforementioned curvature?) Without digressing from the importance of such a discovery, any meaningful relationship between various vector spaces, or, extrapolation of linear measurements can only offer a circumstantial view of spatial positionings of inline linear vectors. A list of circumstantial views follows:

  • Lines with external space occupied by curves.
  • Linear boundaries without any curvature.
  • Space defined only by a curved boundary.
  • Space, undefined, without linear vectors or curves.

This list could go on and on. One may quickly realize that without any kind of spatial curvature, lines (and their linear vector-counterparts) may ultimately be random, and mixed.

Conclusion: careful, non-interpretive, and systematic positioning helps provide a system of measurement with the boundaries required to ascertain the distance between any kind of vector space when curvature is involved!

 

Curvature of Stellar Cosmological Space

Curvature of the stellar cosmological space conforms to inter-dimensional foundations. Overdeveloped curvature and underdeveloped tangential foundations consist of forms that only result in dimensional space analysis when certain standards are applied to the original cosmology. One may assume, “important space, dimension and curvature have intermediate textures as their foundation,” if no regard is given to non-conformist (relativistic) standards when applying thought processes to controlling the measurement.

Stellar dimensional space consists of:
a.) motion
b.) vacuum space
c.) lines and curves
d.) etheric dimensions
e.) countable dimensions

Fluid foundation without curvature consists of:
a.) lack of curvature
b.) foundation that is fluid
c.) foundation without curvature

When fluid foundation is extracted from the excess curvature of stellar cosmological space, an analysis of dimension may conform to some specific and relativistic standard when vacuum space, lack of curvature, and controlled tangential foundations are studied. If one refers to the following illustration (previously shown in the upcoming past lecture), the idea that space has intermediate textures that conform to relativistic standards becomes clear:

controlled tangential foundations

controlled tangential foundations

If one discerns parts of the above displayed illustration, a very odd fluidic motion becomes apparent. When reversed, curves become lines, angular dimension becomes etheric, and fluid changes into a textured dimensional foundation. Three colors are of utmost interest to those who explain their interest to displayed fields of time and dimension. The first color is red, the second color is yellow, and the third color is not currently named, as it has been previously unidentified. Simplistic views of this third color may follow.