We live in a universe where there is more matter than anti-matter. Pre-AuT mathematics is at a loss for such results. Of course, AuT has no such problems and predicts this result.
The creation of standard clock time and space time effect this result so it makes sense that what we're looking for is the dimensional application of f(x).
Looking at the figure below, it is seen that the first carrier state, the ones that will ultimately control the length of time between compression and decompression and between matter and antimatter only come from the first to dimensional states.
The sin solution for pi(0) and for pi(1) both have inflection points that change over time.
It is suggested, at least in o-space mathematics, that one controls the movement between compression and decompression and the other controls the difference between positive and negative spirals, matter vs anti-matter based on whether this carrier is positive or negative.
This alternating features appears to be lost at higher ct states so there are no other features alternating other than the compression vs decompression, defining whether particles and the universe as a whole are tending towards expansion or contraction. The other alternating feature changes the nature of the particles within the expanding or contracting matrix.
The counter between
inflection points is based on the f(pluspix) equation which grows longer which
each value of x. The change is based on
the movement along quantum lengths until the inflection point represented by
the solution of f(pluspix) less the number of changes of x along the carrier
(information arm) changes from positive to negative and changes from positive
to negative changing the result from compressive to decompressive.
A net expansive universe would have
positive results and this may reflect why there is more matter than anti-matter
which suggests that the amount of anti-matter would begin to increase with a
compressing universe till it is greater than the amount of matter.
While this changes at one rate for
pi, for sin ratios it changes at an exponentially slower rate. The amount of stability in the system can, therefore,
be whatever is required depending on which feature is tied to the carrier. In this case, it is suggested that the carrier
is governed by what has always been suggested as the underling carrier, the solution
for positive vs negative in the first time-dimension based carrier, the 64 in ct1
states which last as positive or negative in accordance with the point of transition
when the state changes between positive and negative, matter and anti-matter.
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