07/03/2026
Consequences of Relativity in a System with Memory and a Topological Universe
The first step toward this ontology emerged when applying the principles of special relativity to the double-slit experiment. It became clear that no objective trajectory or temporal evolution exists, only a static configuration and the memory of the observer, which reconstructs it as an interference process in space and time.
This theory is based on the assumption that all paradoxes of quantum mechanics arise exclusively from the mechanism of memory, which compares past events with more advanced ones (closer to the present) and thereby creates the illusion of the flow of time and processes in space.
Physically, the universe is a single static structure in which neither time nor space exist as fundamental entities. Everything we perceive as three-dimensional space, the flow of time, particle motion, or the propagation of fields is an emergent phenomenon arising solely from the interaction of this structure with memory.
Memory in this structure functions as a quasi-machine of time that virtually “travels” into the past. Every act of perception is a comparison of the current state with a stored past one, in this way memory artificially creates the flow of time and the illusion of a causal process in space. Memory (and consciousness) essentially performs virtual time travel, and precisely the paradoxes that would be expected from real time travel appear (delayed choice, quantum eraser, black hole information paradox).
A small example
In the system emission (A) - detector (B), emission and detection are the same instant. The time of emission occurs at the same time as the time of detection.
When we add memory (C) or records that we compare with a later time, we assign an absolute time to emission (A) and detection (B) within a system that originally has no absolute time.
The results are then reconstructed as the motion of a field excitation through space from A to B. However, in the A-B system there exists only entanglement, no propagation occurs. Photon exchange happens exclusively locally on two distant electrons.
A human with memory is not an observer, he is a creator of paradoxes.
1. Consciousness as an Integral Computational Machine
Consciousness (or memory in the broader sense) is not a passive observer, it is an active computational mechanism that integrates (adds, compares, mixes) past states with present ones.
Exactly like a mathematical integral ∫ f(t) dt , consciousness “integrates” stored records (the past) with new clicks (the present) and creates a continuous image of reality.
Consciousness works like an algorithm: it compares phase shifts through extra correlations (mixing A-B-C). Every step is a “calculation”, memory adds phases and antiphases, flips signs, and the resulting reconstruction in memory is interference between past states and advanced ones.
Like an integral that sums infinitesimal parts, consciousness integrates infinitely many small phase shifts into a single whole. For example:
long periods (stable states such as the electron) are “integrated” into eternal stability
short periods (excitations) integrate into rapid decay
Consciousness is the machine that performs these integrals. Without it there would be no “whole”, only isolated clicks.
This is why consciousness generates paradoxes: it is a machine that integrates the past with the present, which looks like backward time travel, and thus loops (delayed choice), rewriting (collapse), or infinite integrals (stability) arise.
2. The Schrödinger Equation Describes the Function of Consciousness More Than Physics
The Schrödinger equation
iħ ∂ψ/∂t = Hψ
is not a description of the physical evolution of reality. Reality is static (a timeless mosaic). The equation describes the function of consciousness, how memory integrates past states with present ones and creates the illusion of continuous evolution.
The time term ∂/∂t
This is not objective time. It is the “integration step” of consciousness, comparing a stored past state (previous click) with an advanced one (current click). Consciousness “derives” changes and “integrates” them into the wavefunction ψ.
Hamiltonian H
This is not a physical operator, it is the “integration operator of consciousness” that sums energetic conditions. Consciousness uses it to reconstruct stable states from excited ones.
Wavefunction ψ
This is not the physical state of a system, it is the “integration map of consciousness”, an interference pattern created by mixing past and present angles.
Thus the Schrödinger equation is a mathematical description of how consciousness “computes” reality from a timeless structure.
Why does it describe consciousness more than physics?
Because without consciousness (without memory) there would be nothing to “integrate”, no ∂/∂t, no ψ. Physics would consist only of static clicks without evolution.
Consciousness is the integral machine that turns clicks into a story.
And the Schrödinger equation is its instruction manual.
The Schrödinger equation is not a law of the universe, it is a law of consciousness that integrates and reconstructs.
Paradoxes arise because consciousness is an integral machine that mixes the past with the present, as if an integral were rewriting the history of a function.
That is why we introduced imaginary planes, because in essence they were always there.
What Then Is Physical Reality?
The fundamental “mechanics” or state of this structure is phase rotation at the Compton wavelength, whose shift changes according to relative acceleration or energy.
The Compton wavelength simultaneously defines time and space and represents the resolution limit of phase shift in memory. Below this scale individual clicks can no longer be distinguished, everything appears simultaneous and dimensionless.
Above this boundary memory begins comparing clicks, creating the illusion of spatial resolution and temporal flow.
When motion or increased energy occurs, the internal rotation dilates and the phase shift becomes distinguishable. This manifests as E and B fields, and at higher energies as electromagnetic radiation.
The entire process is therefore not an excitation of an external field, but an excitation of the particle itself, where energy is defined through the winding number, the ratio of phase shift to the Compton wavelength.
All interactions occur exclusively locally on the particles themselves through changes in winding number.
Even values of the winding number function as communication channels between different particles, not as transmission through space but as entanglement.
All known physical phenomena (electromagnetism, strong and weak interaction, gravity, particle masses, decay, the big bang, radiation and even dark matter) are in this ontology merely different values or transitions of this single topological number.
Electromagnetism
EM is not any flow or transmission but a global entanglement between phase and antiphase (plus and minus components) that excites states in a detector or another particle at a distance without any physical motion or propagation.
This is exactly the mechanism that makes an EM “wave” appear as translation, while in reality it is merely entanglement reconstructed by memory as a field excitation.
How It Works
EM as antiphase entanglement
EM is an excited particle, for example an electron at energy n≈2, where phase (plus component) and antiphase (minus component) are globally entangled, connected without space or time.
This entanglement is simultaneous across the entire timeless structure.
Plus and minus are two sides of one coin existing everywhere at once.
No motion, no propagation, only a global state of two opposing phase orientations on a circle (shift of 180°).
Remote excitation
When this entanglement interacts with a detector (n≈0 state), no energy transfer through space occurs.
Instead, the entanglement excites the detector’s base states remotely by increasing its phase shift (90°).
The detector flips between n=0 and n=1 or n=2 states, which memory reconstructs as the “arrival of a wave”.
Why it appears as a wave
Memory compares the past state with the present detector excitation. This extra correlation creates the illusion of translation.
E and B appear orthogonal because the detector reads the entanglement through perpendicular components.
Memory projects this as two fields.
But EM itself is only entanglement, the detector records its own excitation.
Universe as a Topological Map
The universe is nothing more than a global timeless map of particle states where phase rotates around a circular axis without spatial motion, only rotation, reconstructed by memory as a “slice”.
In this slice we see loops (ordinary, Möbius, intertwined) where each additional winding opens a new charge or state.
The entire cycle repeats from n = infinity to n = 0 (and possibly to negative infinity) as an infinite periodic process.
Each winding opens a new charge: direction reconstructed by memory as charge, spin, electromagnetism or interaction.
Example Values of n
n = 0
One rotation without phase shift. Electron at rest or neutrino-like state.
n = 1
Rotation with a 90° shift. Möbius-like topology. Appears as electromagnetism.
n = 2
Rotation with 180° shift. Higher excited electron state. Appears as a photon.
n = 3
Rotation with 270° shift. Three charges per cycle - quark.
n = 4
Rotation with 360° shift - gluons.
Higher n - black holes, dark matter
n - infinity - the Big Bang.