So, one may inquire, what is the holonomic substrate that works to comprise the Hamiltonian operands of general space-time-fabric? I can see why so many people have been avidly awaiting the suspense that will be eluded to as such in course 13 -- which is about Substringular Transformations. So, as a heads up to this so stated course 13, the holonomic substrate that works to comprise the Hamiltonian operands of general space-time-fabric are the loci where the general phenomena of the ultimate fractal of pressurized vacuum is not kinematically Gliossi to such spots and regions in any of such manner that may here be termed of as Poincaire at the conipoint-based eigenstate-based positionings -- per hermitian-based motion that here involves the motion of such eigenstates of the general phenomena of the ultimate fractal of pressurized vacuum -- that may be marked upon such Laplacian-based delineations of such given arbitrary mappings in open space. This works to describe the phenomena of what open space that is not overtly kinematic as a substringular operation, or, also of what open space that is not overtly kinematic as a substringular operator, must be defined of as in so as to define the existence of non-kinematic-based spatial regions. All spatial regions are made up of at least potential pinpoints that may be mapped of as conipoint-based eigenstates that may have a certain value and/or a characteristic that these derive and may be derived from -- as well as a value and/or a characteristic that these bear over the course of both the Laplacian conditions that these exist in, as well as over the alterior Fourier conditions that their coexisting operators and operations bear over the time that such a latter Fourier condition appertains to -- under whatever given arbitrary overall Ward-Caucy conditions that the overall framework of a certain physical scenario may portray in so as to depict some kinematic activity that happens through that free space that I here define as the holonomic substrate that works to comprise a certain Hamiltonian-based operand-like phenomena. More to that in course 13.
I will continue with the suspense later! By the way, good question!!! Sincerely, Sam Roach.
Catch You "Two!"
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