CM's dialog is good and I want to participate by putting in emphasis here and there.

ISUEEP5-13-07

We must always keep the following in mind when talking about the ISU and the EEP.

It is not practical to think of a universe containing one EEP, but if there was just one, would it expand forever as its tiny quantum amount of energy spread thinner and thinner or would it simply expand and contract by itself in empty space?

I think it would be the latter. If so would each expansion be fulfilling some finite relationship as to full expansion and each contraction reaching some limit as to its own internal density? I think so, and I think that the full expansion and full contraction would have specific limits and would define the space that one EEP could occupy if allowed to fully expand and contract. If so we could assign a constant to the fully expanded size and a constant to the fully contracted size, and assign a function to the pulsing by using a time factor for each full pulse cycle.

It is not practical to think of a universe containing so many EEPs that they could not expand at all. They would be locked in their contracted state and could never have enough space to expand. Even if while in the locked state they had potential to expand they would have no space to expand in. The value of that potential would eventually be derived from the math of the pulsing EEP if it could be quantified, and I think it can be.

Each of the above two cases is an extreme of energy density. One EEP expanding and contracting may only need a tiny amount of empty space to exist and fully pulse representing the lowest possible energy density, while a universe of fully locked EEPs that could not expand at all would have the highest possible energy density.

Energy density of space is the number of EEPs divided by the volume of space that they occupy.

Lets us explore the energy density possibilities that are between those two extremes.

Let us take first a “low energy density environment” where all of the EEPs can fully expand and contract in their own space, there is even room to add more EEPs before you begin to get some overlap. And let us define the term overlap to simply mean that there are too many EEPs in a given space to allow them all to fully expand and contract with intruding on each others required allotment of space. In this low energy density environment there is no overlap.

Let us take next a perfectly “equalized energy density environment” where all of the EEPs can fully expand and contract in their own space, but if you add one more EEP there will begin to be some overlap. This energy density of space (EDS), with complete freedom for each EEP, and yet with the maximum EEPs allowed without overlap we will call the equalized energy density. This is the perfect EDS for an EEP that likes companionship but wants its own space; the perfectly equalized energy density of space.

Not only is this perfect for the comfort loving EEPs, this is the energy density that space seeks to achieve. It is the perfect background. Now don’t take me literally, I am not suggesting that EEPs or space have a mind of their own; I am speaking figuratively. The perfect background is the energy density that allows this perfect relationship between all EEPs and the space that they occupy.

Next let us take an energy density of space that has too many EEPs to allow them each to fully expand and contract in their own sufficient space, but that does not cause them all to be locked so that they can never expand at all. They are only compressed to some degree and go on pulsing with only minor inconvenience.

Just to define that landscape in the most general parameters, this would be termed a high energy density of space that causes there to be some degree of compression at all times. The term compression means that none of the EEPs can fully expand, and before they can fully contract their space is intruded upon by an adjacent EEP and they can never fully contract without intrusion. They are slightly compressed.

Up to this point we have discussed five different energy densities of space: One EEP alone in space, so many EEPs that they can only exist if they are locked in their contracted position, a low energy density environment, the ideal energy density of space, and a moderately high energy density of space.

I think the universe, the greater universe in the ISU, has a high energy density on that scale. And I think that the universe has always existed and has always had this high energy density. High energy density forces matter to exist. The proportion of matter to energy density of space is determined by how high the average energy density of the greater universe is.

The matter that exists is made up of the excess EEPs over and above the ideal background of perfectly "equalized energy density" described above.