Let us initially consider a set of orbifold eigensets -- that go from having a steady-state gravitational force, that is to here be correlative between them -- in a manner that is both covariant, codifferentiable, and codeterminable among them, to then going into what entails of as subsequently having an anharmonic gravitational force, that is to here be correlative between them in a manner that is both covariant, codifferentiable, and codeterminable among them, to then going back into having a relatively steady-state gravitational force that is of the so-eluded-to relatively tightly-knit tense of a Majorana-Weyl-Invariant-Mode. This will consequently be of a tense, of what would initially work to form as a Reimman-based scattering, that is later to be anharmonically perturbated into a Rayleigh-based scattering, that is to then later be harmonically perturbated back into a tense of a Reimman-based scattering. Let us next consider, that the region that is to be proximal localized to the general spot, where such a basic sequential series of gravitational perturbation is to occur, is of the same internally covariant, codeterminable, and codifferentiable reference frame. This will then tend to mean, that the adjacent eigenindices, that are to here to have been scattered -- via the so-eluded-to basic sequential series of gravitational-based perturbative translation, will go from bearing what will in reality be of an indistinguishably different state of a set of eigenstates, that will go from bearing a multiplicit proximal localized chirality -- that is made to be relatively homogeneous in an even manner, to then subsequently bearing a multiplicit proximal localized chirality -- that is made to be relatively homogeneous in an odd manner, to then subsequently bearing a multiplicity proximal localized chirality -- that is made to be relatively homogeneous in an even manner, and so on, -- via the so-eluded-to sequential series that I had earlier implied of as happening.
I will continue with the suspense later! To Be Continued! Sincerely, Samuel David Roach.
No comments:
Post a Comment