Thanks for those links Rowanda.
Now I get it (what Cahill is on to).
Haven't got a computer or internet but from your references I can see thanks to something I found in a book.
The Michelson Morley experiment, I read, did not in fact produce a nil result. Nor did later versions of the experiment.
It produced a small discrepancy that was dismissed by some as experimental error.
My interpretation of the MM experiment was that it did not prove the speed of light was constant in all directions because it could not see direction.
The experiment splits a light beam into a fourway rightangled scenario. People assume that the space containing the experiment is rigid (or 4D grid spacetime with fixed scale.
(A 4D space with time condensed as a 3/3 frequency (a light beam).
A split then recombined light beam against a "lightbeam" space doesn't know where it went or what direction only that it went somewhere inside itself. So it is like a selfreferent nanostructure.
The experiment defines 4D against an assumed 4D rendering direction invisible....except that direction is slightly defined by the experiment due to internal direction: as the experiment has scale and an outer boundary; direction is locally defined by lines pointing inwards to the center of the experiment.
The sum of many compared experiments locally defined scalecollapse inwards (their internal direction)(so no wonder Cahill talks of "smart nanostructures") would give "other ways the experiments COULD generate mutual space.
This gives a global "ghost" Michelson Morley experiment involving all little Michelson Morley experiments: its sense of direction is a map of where each experiment is reference each other.
This gives "background radiation" concealed within the complementarity of all the MM experiments. One lone MM experiment would give a perspective on the other posibile MM experiments as a reflection of "outer space" through inner space.
Ayattempt to group some MM experiments together will generate a "scale of scale" constant if described by nillscale (mathematics). Can call that "Planck's constant".
Can compare MM groups and conserve your Planck constant by blowing quantum foam (math in math) with a Hubble constant (expansion of your MM containing universe via contraction of your MM's definition space due to Planck:Planck shrinkage (or conserve your Planck:Planck call it "Neutron star" and have time dilation (to make the shrinking gauge look like it isn't shrinking you have to imagine stretching time (stretching your reference space against which you calibrate your object)
Fine structure constant: fine structure suggests a deal between locally selfreferent items (such as MM experiments).
To hold a group of MM's in a constant fine mutual room from the swappability potential among their internal spaces: requires looking at their mutual definition of mass (of internal room to move): this is called "inertia".
To see "mass" and "inertia" would require a deal )a constant) of finestructure: that is a map of locality of the MM's.
To describe a fine structure constant in mathematics would require, since math treats locality and map as collapsed (by assuming numbers are equal) breaking math into two groups, allowing the MM's localities to be nonlocal in a complementary superposition of alternative maps.
This gives the impression of two universes colliding; thus of gravitational waves (but to describe these requires a quantum foam background: real numbers.
To see a mutual map from superposed maps (to have a global positioning system) would require inflowing the nonlocal MM's (making them more local).
Selfreferential noise:
Math: 1+ 1 = 2 then 2 + 1 = 3 etc. how know the ones are equalsized? By going back in time and redefining the first two ones as thirds of the new space that includes a new one.
dolphin
