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Quantum theory is quite consistent with relativity in many respects. The wave function of a system always travels at the speed of light. It allows us to predict the behavior of electro-dynamic systems. Einstein presented special relativity as a theory of electro dynamics where the nature of light determines everything else.

Light, in essence represents the exchange of momentum between electrons or their equivalent, or in quantum state space, momentums propagating at light speed, ultimately transferring momentum from one system to another. This underlying mechanism mediates all momentum exchanges. When you push on something, the electron interactions exchange the momentum where the change in momentum defines the energy of the light (photon) in every case.

Quantum theory only considers the system from the point of view of a single clock, suggesting absolute time, and preferred clock, contrary to relativity. However, the indeterminacy of time direction in the quantum allows for the relative nature of time relativity exposes.

Quantum state is manifest as changes. An occupied state has been evacuated when it is perceived. The change of state defines distance at light speed manifesting spacetime. While state space represents potentially infinite local dimensions, only states that change are actually manifest, making actual spacetime dimension a subset of infinite spacetime dimension.

If the vacuum is only marginally less energy dense than matter, as proclaimed by Wheeler and others, then indeed all spacetime is manifest in the same manner, by quantum system exhibiting state space.

Spacetime actualized in this manner does not exhibit any fixed dimensional background coordinate system.

State space is nothing more than momentum in time and space, traveling at light speed. This includes dimensions that span our ordinary 3D plus internal local dimensions which manifest mass by delaying energy they receive as if the light travels further inside than the external dimension suggests would be possible. Relativity accounts for this phenomenon as a stretching of timespace due to mass. Quantum theory exposes how this extra dimensionality is manifest as orthogonal transformations in state space matrices. Momentum in state space accounts for the behavior of quantum systems to at least 24 decimal places. There is no room for relativity or other hidden influences. The quantum mechanical description must be complete, and include the effects of relativity or we would get different answers. Hidden variables (influences) have been excluded.

Quantum theory, today, does not consider the vacuum to be composed of ordinary energy. It is postulated as random. This forces us to paste on special relativity as something different than quantum theory when dealing with microcosmic systems as is done in Dirac's equations and QED. This is an area where modern quantum theory is incomplete. It is claimed that gravity is not accounted for in quantum theory. This is a logical contradiction. Entropy in quantum systems, is ineviable. The entropy of timespace discriminations can account for gravity. This is the essence of modern theories of quantum gravity. The mistake is to consider anything other than ordinary electro dynamics, as that has already been excluded.

Spacetime is undistinguishable from dynamically actualized quantum state space as exhibited by the kinetic exchanges of momentum.

If we consider the Hilbert state space (p,x,y,z,s,t)

p = momentum = mass*velocity, momentum exchanges alone manifest mass and velocity in integer counts of Plank actions.

s=spin, a binary, relative value, manifesting independence in orientation, or not. Independent relative binary orientations may share the same state with respect to position and momentum..

t=time, the inverse of integer counts of aligned Plank actions, or energy e=h*f, f=1/t, t=e/f, t=x/c.

x,y,z=position to a precision of integer counts of Plank actions x=t*c.

Momentum, and hence, the manifestation of mass and velocity, depend on relative motion. We can define relative state as a mapping of momentum and position between the rest frames of the participants based on motion.

We can assume quantum state that is not occupied, it not manifest. We only need consider the relative spate between the participants. This is necessary as relative state space may manifest infinite dimensions (with infinite participants).

Discrete electron ballistics manifest momentum exchanges. t'Hooft showed random samplings of these are consistent with quantum probabilities.

Electrons attempting to occupy and occupied state, reflect, otherwise they transmit, or propagate, as in the vacuum, instantiating time and space unchanged. (reflection is like doubling). The implication that exclusion from common state is the only thing in quantum mechanics that manifests independent state suggests a simple ballistic interpretation if we allow quantum state to be dynamic, as its nature suggests it must be.

As Wheeler pointed out, matter is percentage wise, only marginally more dense than the vacuum. Like the vacuum, matter consists of energy or propagating differences. Most signals propagate through matter as easily as through the vacuum. It is only the signals frequencies that an object is "tuned" to receive that are stopped. The only thing that can stop the signal in quantum mechanics is the attempt to occupy and occupied state. State may exist at each Plank length which accommodates differences changing at each unique energy (momentum) in plank units. Excluding occupation of occupied states forces the manifestation of independent state. That is the same mechanism that prevents objects from passing through each other. The total frequency of interaction of a mass is determined by its mass, f=m*c2/h. In the quantum, this is how often it manifests state.

The vacuum is composed of only low energy signals (only low momentum occupied states) such that the momentums of higher energy signals are never occupied and the higher energy signals are never impeded. Mass seems solid because higher energy states are occupied forcing reflection of other masses and some signals. Xrays, for example, are high enough energy to pass through many objects without reflection due to the inability to proceed without occupying occupied energy levels. Conversely masses, which posesses much higher energy, move though the vacuum a constant velocity unimpeded by it.

Relative state space allows us to selectively understand the interactions of selected participants and the effects (or non-effects) of the vacuum.

See KineticQuantumClockwork QuerkCalculus EquivalencePrinciple DiscreteRelativity QuantumRelativity ObjectiveInformationPhysics WhitescarverModel

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