S-classification boundaries in the S-structure of the universe

In the previous chapters it was shown that the most typical representatives of the thirteen main classes of objects of the Universe are located on the S-axis with strict periodicity in five and ten orders of magnitude. In doing so, we used the geometric mean sizes of the selected objects. Recall that this parameter was defined as the midpoint of the scale range of the objects' existence. For this purpose, the dimensional boundaries for each studied class (minimum and maximum) were marked on the S-axis, and then the midpoint of the obtained segment was found.

The logical development of this scheme led the author to the construction of the S-WAVE of stability . Then it unexpectedly turned out that the SWS MODEL has additional heuristic possibilities. For example, in many cases the permissible range of object sizes coincides with the points of intersection of SWS and S-axis, and the scaling length of this range in many cases is equal to five orders of magnitude. That is, not only the main objects of thirteen classes of the Universe are located at a distance of five orders of magnitude from each other, but the scaling range of eleven of them is also almost always equal to five orders of magnitude. At the same time, each upper half-wave of the SWS, having a scaling length of five orders, as we have already said, is "populated" mainly by structural objects, and each lower half-wave - by nuclear objects. Moreover, it turned out that the upper and lower inflection points of the SWS are also classification boundaries, but within each of the thirteen classes. Since the special points on the SWS (inflection points and points of intersection with the S-axis) alternate in 2.5 orders, this model gives us a hierarchical scale classification. In this classification, there are large cells whose scaling length is twenty orders of magnitude. These large cells are subdivided into cells of ten orders of magnitude, which in turn are subdivided into cells of five orders of magnitude, and those into cells of 2.5 orders of magnitude. Moreover, as will be shown, cells of fifteen orders of magnitude also make physically real sense. All this suggests a complex combination of different classes with each other. It can hardly be taken as a coincidence, so the author had a PROPOSITION that the , constructed at the first stage simply as an image of stability of objects, is also a convenient classification matrix for large-scale division of the Universe floors. Let us show to what extent this assumption corresponds to the facts.

We start the analysis with the largest classification division of SW into three identical sections of about twenty orders of magnitude each.