Wednesday, December 4, 2019
Lorentz-Four-Contraction And Relative Length
Let us initially consider a mass-bearing orbifold eigenset to be moving, at just under the speed of light. It's Lorentz-Four-Contraction, is here to be 3*10^8. The given arbitrary respective orbifold eigenset, is here to be traveling in the relative forward-holomorphic direction. The said eigenset is here to work to bear 3*10^8 times as much mass, than it would normally have, when at a relative terrestrial standstill. This will then work to mean, that this said given arbitrary orbifold eigenset, is here to work to bear the proximal local presence, -- of 3*10^8 times as many mass-bearing superstrings of discrete energy permittivitiy, than it normally would have, if at a relative terrestrial standstill. This will then work to mean, that such a said orbifold eigenset, is here to tend to be quite significantly denser, -- than it would otherwise be, if it were, instead, to be traveling at a much slower rate, in relation to the motion of light. Since the said respective orbifold eigenset, is here to be much denser -- it is here to bear a much greater gravitational wave-tug, upon its immediate physical environment, at a level that is Poincare to the general spatially differentiable region, at which the inferred eigenset is to be moving through. Since the said eigenset is here to work to bear a greater gravitational wave-tug for its size, it will consequently tend to work to draw its composite mass-bearing superstrings of discrete energy permittivity inward, in a euclidean manner, that is of a proportionality, that is correlative to the directly corresponding Lorentz-Four-Contraction. This will thence, tend to work to make the length of the initially stated orbifold eigenset, -- when this is here to be taken in the holomorphic direction of its motion, that is here to be at just under light speed, -- to tend to bear a Lorentz-Four-Contraction, when this is taken in a relativistic manner to a terrestrial observer, to then become thinner, by a factor of 3*10^8. I will continue with the suspense later! To Be Continued! Sincerely, Samuel David Roach.
Posted by
samsphysicsworld
at
11:10 AM
Labels:
euclidean,
holomorphic direction,
orbifold eigenset,
region
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