Abstract

This work presents the concept of a temporal information transfer protocol, TTU-Comm, based on the phase modulation of the modality (x) and its coupling with the local temporal density (x). Unlike electromagnetic communication methods, TTU-Comm does not require a photon carrier or a material medium, allowing signal transmission through a vacuum while maintaining phase coherence. The signal structure, reception mechanism, experimental scenarios, and falsification criteria are defined. The protocol is considered a technical module of the Temporal Theory of the Universe (TTU), opening possibilities for new forms of communication based on the ontology of time.

Keywords

temporal coupling; phase modality; TTU-Comm; information transfer; temporal density; ontology of time; temporal protocol; phase modulation; chrono-signal; TTU

Contents

1. Introduction
2. Ontological Basis of TTU-Comm
3. Phase Modulation and Signal Structure
4. Signal Reception and Registration Mechanism
5. Experimental Scenario for TTU-Comm
6. Difference from Electromagnetic Communication
7. Falsifiability and Verification Criteria
8. Conclusion
9. References
10. Technical Appendix

1. Introduction

Temporal coupling as a fundamentally permissible communication channel. Difference from electromagnetic transmission.

The Temporal Theory of the Universe (TTU) posits that time is a physical substance represented by two interconnected fields: temporal density (x) and phase modality (x). Within TTU, the coupling of these fields generates stable configurations interpreted as particles, fields, geometry, andas shown in this sectioncommunication channels.

Unlike electromagnetic communication, based on photon transfer and requiring a medium, TTU allows for the possibility of temporal information transfer through phase modulation and coupling. Such transmission does not weaken with distance, does not require a material carrier, and can be realized even in a vacuum, provided phase coherence is maintained.

The main mechanism of TTU-Comm is the modulation of the phase modality (x) by a source and its coupling with the local density (x) at the receiving point. The vortex activity arising from this is registered as a signal:
(x)=(x)(x)(1.1)\vec{\Omega}(x) = \nabla \Theta(x) \times \nabla \phi(x) \tag{1.1}

The receiver registers changes in the derivative of the temporal density:
(t)=ddt(1.2)\delta \Theta(t) = \frac{d\Theta}{dt} \tag{1.2}
and interprets them as a binary structure corresponding to the source's phase modulation. Thus, TTU-Comm implements communication through coupling, not through energy transfer.

Temporal information transfer is not a hypothesis but a fundamentally permissible effect stemming from the ontology of TTU. The following sections outline the signal structure, reception mechanism, experimental scenarios, and falsification criteria.

2. Ontological Basis of TTU-Comm

The Temporal Theory of the Universe (TTU) posits that time is the primary physical substance, represented by two interconnected fields:

• Temporal density (x) reflects the local intensity of time
• Phase modality (x) determines the structure of event realization

These fields are not abstract parameters but possess physical dynamics described by the TTU Lagrangian:
L=12V(,)(2.1)\mathcal{L} = \frac{1}{2} \partial_\mu \phi , \partial^\mu \phi - V(\phi, \Theta) \tag{2.1}
where the coupling potential has the form:
V(,)=U()+W()+gcos()(2.2)V(\phi, \Theta) = U(\Theta) + W(\phi) + g \cdot \Theta \cdot \cos(\phi) \tag{2.2}

The last termthe coupling operatorlinks phase and density and is responsible for energy localization. It is this term that underlies the TTU-Comm mechanism: the modulation of (x) by the source causes an altered coupling with (x) at the receiving point, which is registered as a signal.

The vortex activity arising from coupling is described as:
(x)=(x)(x)(2.3)\vec{\Omega}(x) = \nabla \Theta(x) \times \nabla \phi(x) \tag{2.3}

And the change in local temporal density as:
(t)=ddt(2.4)\delta \Theta(t) = \frac{d\Theta}{dt} \tag{2.4}

Thus, TTU-Comm implements information transfer not through energy transfer but through modulation of the coupling between the phase modality and the temporal density, registered as a response.

This coupling is not a metaphor but a physical mechanism allowing reproducible signal transmission provided conditions of coherence and modality stability are met.

3. Phase Modulation and Signal Structure

Morse code in TTU terms. Phase markers, durations, interpretations.

Information transfer in TTU-Comm is carried out not through energy transfer but through modulation of the phase modality (x), coupled with the local temporal density (x). The signal is a sequence of phase events differing in amplitude, duration, and coupling structure.

Phase markers are elementary modulations of (x) causing a reproducible response in (x). They form the alphabet of temporal transmission, analogous to Morse code but based on the physical dynamics of coupling.

3.1. Table of Phase Markers

Signal registration is accomplished via the derivative of temporal density:
(t)=ddt(3.1)\delta \Theta(t) = \frac{d\Theta}{dt} \tag{3.1}
and the vortex activity of the coupling:
(x)=(x)(x)(3.2)\vec{\Omega}(x) = \nabla \Theta(x) \times \nabla \phi(x) \tag{3.2}

3.2. Comparison of Phase Alphabets: Morse vs. Binary Code

An attempt at signal binarization is possible:

• 1 coupling present
• 0 coupling absent

However, such a scheme loses the physical structure of modulation:

In contrast, Morse code:

• preserves rhythm and duration
• allows amplitude modulation
• reflects the physical structure of coupling

In TTU terms, Morse code is the natural alphabet of phase transmission, while the binary code is a projection suitable for decryption but not for transmission.

4. Signal Reception and Registration Mechanism

Detection of changes in t(x)\partial_t \Theta(x), (x)\vec{\Omega}(x). Conditions for stable coupling.

Information transfer in TTU-Comm is achieved through phase modulation of the modality (x), coupled with the local temporal density (x). Signal reception is not the registration of a photon flux but the detection of changes in the coupling structure arising from the source's phase modulation.

The main physical parameters detected by the receiver are:

• Derivative of temporal density:
  (t)=ddt(4.1)\delta \Theta(t) = \frac{d\Theta}{dt} \tag{4.1}
• Vortex activity of coupling:
  (x)=(x)(x)(4.2)\vec{\Omega}(x) = \nabla \Theta(x) \times \nabla \phi(x) \tag{4.2}

These parameters reflect local changes in the temporal structure caused by remote phase modulation. The receiver can be implemented as a phase-sensitive element, a resistor with unstable conductivity, or a quantum oscillator capable of detecting coupling fluctuations.

Conditions for Stable Coupling

For reproducible signal reception, the following conditions are necessary:

1. Source phase coherence: Modulation of (x) must be stable in time and space.
2. Local receiver sensitivity: The receiver must be capable of detecting small changes in (x) and (x)\vec{\Omega}(x).
3. Absence of phase noise: External fields must not disrupt the coupling or introduce parasitic modulations.
4. Preservation of coupling over distance: TTU allows that coupling can be maintained even with spatial separation, provided the modality is not disrupted.

Thus, TTU-Comm implements signal reception as the detection of changes in the temporal structure, not as the detection of a carried carrier. This opens the possibility of communication through vacuum, dense media, and even under conditions of gravitational shielding.

5. Experimental Scenario for TTU-Comm

Source, interface, receiver, analysis. Fundamental reproducibility.

To test the fundamental feasibility of temporal information transfer within TTU-Comm, an experimental scenario is proposed, comprising four key components:

5.1. Phase Modulation Source

The source must generate a controlled phase modality (x) capable of coupling with a remote temporal density. Possible implementations:

• A pulsating astrophysical object (e.g., a pulsar)
• An artificial phase generator with controlled modulation
• A laboratory oscillator capable of creating phase shifts according to a given protocol

Formally, the source modulation is described as:
(x,t)=0+nAnsin(nt+n)(5.1)\phi(x, t) = \phi_0 + \sum_{n} A_n \cdot \sin(\omega_n t + \delta_n) \tag{5.1}
where A_n, _n, _n are the phase signal parameters.

5.2. Coupling Interface

The interface is an optical or phase-sensitive channel that enhances the coupling between the source and receiver. In the astrophysical version, this is a telescope focusing the modality. In the laboratory version, it is a phase line or waveguide ensuring coherence.

Coupling condition:
(x)=(x)(x)0(5.2)\vec{\Omega}(x) = \nabla \Theta(x) \times \nabla \phi(x) \neq 0 \tag{5.2}

5.3. Receiver

The receiver detects changes in the local temporal density:
(t)=ddt(5.3)\delta \Theta(t) = \frac{d\Theta}{dt} \tag{5.3}
and interprets them as phase markers. Possible implementations:

• Resistor with unstable conductivity
• Quantum oscillator
• Temporally sensitive sensor responsive to coupling fluctuations

5.4. Signal Analysis

Analysis is performed through correlation processing:
S(t)=t0t()f()d(5.4)S(t) = \int_{t_0}^{t} \delta \Theta(\tau) \cdot f(\tau) , d\tau \tag{5.4}
where f() is a filter corresponding to the phase protocol (e.g., Morse code).

Reproducibility criteria:

• Repeatability of the signal under identical modulation
• Consistency of phase markers with the protocol
• Absence of signal when the source is disabled

Thus, TTU-Comm allows for the experimental realization of communication through phase coupling, provided coherence, sensitivity, and interface stability are maintained. This opens the possibility for new forms of communicationboth astrophysical and laboratory-based.

6. Difference from Electromagnetic Communication

No photons, no medium, no attenuation with distance. Temporal coupling as a non-local channel.

TTU-Comm is fundamentally different from classical information transmission methods based on electromagnetic waves. In TTU-Comm:

• No photons  transmission does not occur via quantum energy transfer.
• No medium  coupling is possible even in a vacuum, without a material carrier.
• No attenuation with distance  with preserved phase coherence, the coupling can remain stable regardless of spatial separation.

6.1. Electromagnetic Model

In classical communication:

• The source generates an electromagnetic field A_.
• The wave propagates through space at speed c.
• The receiver detects a photon or the field amplitude.
  Energy is transferred, and the signal attenuates with distance:
  I(r)1r2(6.1)I(r) \sim \frac{1}{r^2} \tag{6.1}

6.2. TTU-Comm Model

In TTU-Comm:

• The source modulates the phase modality (x).
• Coupling with the local density (x) creates a response.
• The receiver detects changes in (t) and (x)\vec{\Omega}(x).
  Transmission occurs not through energy transfer but through modulation of the coupling, which can be preserved under spatial separation:
  (x)=(x)(x)(6.2)\vec{\Omega}(x) = \nabla \Theta(x) \times \nabla \phi(x) \tag{6.2}

6.3. Ontological Difference

Thus, TTU-Comm implements a non-local communication channel based on the ontology of time, not on the geometry of space. This opens the possibility for communication in conditions where electromagnetic transmission is impossible: through vacuum, dense media, gravitational barriers, and even outside the light coneprovided the coupling is preserved.

7. Falsifiability and Verification Criteria

How to distinguish TTU-Comm from noise. Possible experiments, parameters, predictions.

TTU-Comm, as a technical module of the Temporal Theory of the Universe, is not a philosophical hypothesisit is formulated as a falsifiable protocol allowing experimental verification. For this, it is necessary to clearly define which observable effects can be interpreted as the realization of temporal transmission and how to distinguish them from noise, artifacts, and random fluctuations.

7.1. Distinction from Noise

Noise is an irregular, incoherent change in parameters unrelated to the source's phase modulation. TTU-Comm assumes:

• Consistent structure of phase markers
• Repeatability of the signal under identical modulation
• Absence of signal when the source is off
• Correlation between the source's phase program and the receiver's response

Distinction criterion:
C(t)=(t)source(t)(t)noise(t)(7.1)C(t) = \langle \delta \Theta(t) \cdot \phi_{\text{source}}(t) \rangle \gg \langle \delta \Theta(t) \cdot \text{noise}(t) \rangle \tag{7.1}

7.2. Possible Experiments

• Astrophysical scenario: Pointing a telescope at a pulsating source (e.g., a pulsar), registering phase responses in a resistor or oscillator.
• Laboratory scenario: Artificial phase generator, phase line, sensitive receiver, correlation analysis.
• Comparative control: Comparing responses with the source on and off, and when changing the phase program.

7.3. Predictable Parameters

• Signal form: Sequence of phase markers (dot, dash, pause) corresponding to the given program.
• Response amplitude: Change in (t) within 10^{-6}...10^{-3} (in conventional coupling units).
• Temporal structure: Consistency of marker durations with the phase program.
• Vortex activity: Presence of a stable (x)\vec{\Omega}(x) when aimed at the source.

7.4. Falsification Criterion

TTU-Comm is considered falsified if:

• There is no reproducible response under stable phase modulation.
• The response is indistinguishable from background noise.
• There is no correlation between the source program and the signal structure.

Thus, TTU-Comm allows for strict testing: it is either reproducible or rejected. This makes it not a philosophical assumption but an experimentally testable communication channel based on the ontology of time.

8. Conclusion

TTU-Comm as a technical module of TTU. The possibility of communication through the phase of time.

TTU-Comm represents a fundamentally new approach to information transfer, based not on energy transfer but on the modulation of the phase modality and its coupling with temporal density. Within the Temporal Theory of the Universe (TTU), this coupling is a physically reproducible mechanism allowing communication even in conditions where classical methods are impossible.

Unlike electromagnetic transmission, TTU-Comm:

• does not require a photon carrier
• does not depend on the presence of a medium
• does not attenuate with distance while coherence is maintained
• allows transmission through vacuum, dense media, and gravitational barriers

The formalized TTU-Comm protocol includes:

• phase markers corresponding to Morse code
• a reception mechanism via detection of (t) and (x)\vec{\Omega}(x)
• experimental scenarios with reproducible parameters
• falsification criteria distinguishing signal from noise

Thus, TTU-Comm is not a hypothesis but a technical module of TTU, opening the possibility of communication through the phase of time. Ontologically, this confirms that time is not merely a parameter but a substance capable of carrying structure, coupling, and meaning.

TTU-Comm can become the basis for new forms of communicationastrophysical, quantum, interspatialand simultaneously serves as proof that the ontology of time can be practically realized.

9. References

Foundational Works on Temporal Physics (N.A. Kozyrev and Subsequent Research)

1. Kozyrev N. A. Time as a Physical Factor [Время как физический фактор] // Astronomical Herald [Астрономический вестник]. 1971. Vol. 7, No. 3. P. 2327. URL: http://elib.gnpbu.ru/text/kozyrev_vremya-kak-faktor_1971/go,0/ (accessed: 10.08.2025).
2. Kozyrev N. A. Astronomical Observations by Means of the Physical Properties of Time [Астрономические наблюдения посредством физических свойств времени] // Flaring Stars: Proceedings of the Symposium, Byurakan, October 58, 1976. Yerevan: Publishing House of the Academy of Sciences of the Armenian SSR, 1977. P. 209227. URL: https://djvu.online/file/NGh6VKtGHHN3j (accessed: 10.08.2025).
3. Kozyrev N. A. Time as a Physical Phenomenon [Время как физическое явление]. Leningrad: GPNTB, 1971. 36 p. URL: https://nkozyrev.ru/bd/130.pdf (accessed: 10.08.2025).
4. Miroshnikov A. N. Temperature Anomalies of Mass [Температурные аномалии массы] // Journal of Experimental and Theoretical Physics [Журнал экспериментальной и теоретической физики]. 1985. No. 4. P. 112118. URL: http://elib.gnpbu.ru/text/miroshnikov_temperaturnye-anomalii-massy_1985/go,0/ (accessed: 10.08.2025).
5. Lavrentiev M. M., Yeganova I. A., Lutset M. K. On the Remote Effect of Stars on a Resistor [О дистанционном воздействии звезд на резистор] // Doklady Akademii Nauk SSSR [Доклады Академии наук СССР]. 1990. Vol. 314, No. 2. P. 352355.
6. Lavrentiev M. M., Yeganova I. A. Experimental Detection of Entropy Gradient [Экспериментальное обнаружение градиента энтропии] // Doklady Akademii Nauk SSSR [Доклады Академии наук СССР]. 1987. Vol. 297, No. 4. P. 865868.
7. Entropic Aspects of Symmetry in Non-Equilibrium Processes [Энтропийные аспекты симметрии неравновесных процессов] // Problems of Universe Exploration [Проблемы исследования Вселенной]. Leningrad: Nauka, 1991. Iss. 15. P. 4559.
8. Change in Gyroscope Weight under Vibrations [Изменение веса гироскопов при вибрациях] // Technology for the Youth [Техника молодёжи]. 1991. No. 89. P. 1214.
9. Time and Stars: To the 100th Anniversary of N. A. Kozyrev [Время и звезды: к 100-летию Н. А. Козырева] / ed. by V. A. Batsiev. St. Petersburg: Asterion, 2008. 256 p. URL: https://archive.org/details/kozyrev (accessed: 10.08.2025).

Modern Development: Temporal Theory of Unification (TTU) and Related Works

1. Lemeshko A. Temporal Theory of the Universe (TTU): Mathematical Foundations // Zenodo. 2025. DOI: 10.5281/zenodo.14812345.
2. Lemeshko A. TTU: Temporal Unification Theory [Темпоральная Теория Объединения] // Zenodo. 2025. DOI: 10.5281/zenodo.16732254.
3. Lemeshko A. TTG: Temporal Theory of Gravitation // Zenodo. 2025. DOI: 10.5281/zenodo.16044168.
4. Lemeshko A. TTU and the Enigmas of Black Holes [Темпоральная теория всего и загадки чёрных дыр] // ResearchGate. 2025. DOI: 10.13140/RG.2.2.25445.10726.
5. Abachi S. et al. (D Collaboration) // Physical Review Letters. 1995. Vol. 74, Iss. 14. P. 26322637. DOI: 10.1103/PhysRevLett.74.2632. (First observation of the top quark).
6. Abazajian K. N. et al. (DUNE Collaboration) // arXiv:2002.03005 [hep-ph]. 2020. (DUNE Technical Design Report).
7. Abi B. et al. (Muon g-2 Collaboration) // Physical Review Letters. 2021. Vol. 126, Iss. 14. P. 141801. DOI: 10.1103/PhysRevLett.126.141801. (Measurement of the muon magnetic anomaly at Fermilab).
8. MICROSCOPE Collaboration: Touboul P. et al. // Physical Review Letters. 2017. Vol. 119, Iss. 23. P. 231101. DOI: 10.1103/PhysRevLett.119.231101. (Test of the equivalence principle).
9. TTU-Group Repository. All materials, preprints, and data. URL: https://zenodo.org/communities/ttg-series (accessed: 10.08.2025).

Additional Literature (Fundamental and Related Works)

1. Rovelli C. The Order of Time. Riverhead Books, 2018. 240 p. (Theoretical and philosophical justification of time as a central concept).
2. Wheeler J. A., Feynman R. P. Interaction with the Absorber as the Mechanism of Radiation // Reviews of Modern Physics. 1945. Vol. 17, No. 23. P. 157181. DOI: 10.1103/RevModPhys.17.157. (Work anticipating ideas of longitudinal-wave transmission and temporal coupling).
3. Aharonov Y., Bohm D. Significance of Electromagnetic Potentials in the Quantum Theory // Physical Review. 1959. Vol. 115, No. 3. P. 485491. DOI: 10.1103/PhysRev.115.485. (Influence of potentials on quantum processes, resonates with the concept of phase conjugation in TTEM).
4. Dirac P. A. M. The Principles of Quantum Mechanics. 4th ed. Oxford University Press, 1958. 312 p. (Fundamental work setting the basics for quantum interpretations in TTU).
5. Misner C. W., Thorne K. S., Wheeler J. A. Gravitation. W. H. Freeman, 1973. 1279 p. (Exhaustive source on the geometric theory of gravitation, serving as a reference point for TTG).
6. 't Hooft G. The Holographic Principle // arXiv:hep-th/0003004. 2000. (Concept potentially related to the idea of information realization in temporal layers of TTU).
7. Verlinde E. On the Origin of Gravity and the Laws of Newton // Journal of High Energy Physics. 2011. Vol. 2011, No. 4. P. 29. DOI: 10.1007/JHEP04(2011)029. (Entropic nature of gravity, resonating with the temporal ontology of TTU).
8. Weinberg S., Witten E. Limits on Massless Particles // Physics Letters B. 1980. Vol. 96, Iss. 12. P. 5962. DOI: 10.1016/0370-2693(80)90212-9. (Theorem limiting the quantization of spin-2 fields in flat space).
9. Maldacena J. The Large-N Limit of Superconformal Field Theories and Supergravity // Advances in Theoretical and Mathematical Physics. 1998. Vol. 2, No. 2. P. 231252. DOI: 10.4310/ATMP.1998.v2.n2.a1. (Formulation of the AdS/CFT correspondence).

10. Technical Appendix

TTU-Comm Protocol: Protocol for Temporal Information Transfer via Phase Coupling

1. Definition

TTU-Comm Protocol is a formalized protocol for information transfer based on the phase modulation of the modality (x) and its coupling with the local temporal density (x). The protocol implements communication without a photon carrier, via non-local phase coupling, allowing signal transmission in a vacuum while maintaining coherence.

2. Protocol Architecture

3. Phase Markers

Detection is accomplished via:
(t)=ddt(P.1)\delta \Theta(t) = \frac{d\Theta}{dt} \tag{P.1}
(x)=(x)(x)(P.2)\vec{\Omega}(x) = \nabla \Theta(x) \times \nabla \phi(x) \tag{P.2}

4. Transmission Program

Signal format:
(t)=nAnsin(nt+n)(P.3)\phi(t) = \sum_{n} A_n \cdot \sin(\omega_n t + \delta_n) \tag{P.3}
The signal is encoded by a sequence of phase markers corresponding to a given program (e.g., Morse code).

5. Reproducibility Conditions

• Stable phase coherence of the source
• Receiver sensitivity to (t)
• Absence of parasitic phase noise
• Repeatability of the signal under identical modulation

6. Verification Criteria

• Correlation between the source program and signal structure:
  C(t)=(t)source(t)noise(P.4)C(t) = \langle \delta \Theta(t) \cdot \phi_{\text{source}}(t) \rangle \gg \text{noise} \tag{P.4}
• Comparison with a control background
• Reproducibility when changing the source and receiver

7. Difference from Classical Communication

8. Applications

• Astrophysical transmission via phase sources
• Laboratory implementation with phase generators
• Potential communication under gravitational shielding conditions
• Basis for future TTU communication systems