Theoretical and Conceptual Fundamentals of System Computing – Quantum Oscillatory TQC/NMSI

Computer Science & Engineering: An International Journal (CSEIJ), Vol 15, No 2, April 2025
DOI:10.5121/cseij.2025.15201 1
THEORETICAL AND CONCEPTUAL FUNDAMENTALS
OF SYSTEM COMPUTING – QUANTUM
OSCILLATORY TQC/NMSI
Sergiu Vasili Lazarev
Researcher in Theoretical Physics and Cosmology, Bucharest, Romania
ABSTRACT
This article introduces the theoretical and conceptual foundations of the TQC/NMSI system—a novel
architecture based on subquantum oscillatory logic, integrating the New Infobitic Subquantum Mechanics
(NMSI) framework. Within this paradigm, information forms the fundamental substrate of reality, and
“infobits” represent the essential units composing the subquantum vacuum. Quantum entanglement,
nonlocality, and coherence emerge as manifestations of deeper, synchronized patterns within this infobitic
field. The TQC/NMSI system utilizes entangled oscillatory qubits, stabilized by infobitic correlations, for
ultra-sensitive detection of resonance phenomena. The system is designed as an oscillatory quantum
network capable of detecting gravitational, electromagnetic, and geophysical anomalies through
resonance node amplification. The paper extends the notion of resonance nodes to planetary-scale
interactions, where celestial alignments form critical configurations that modulate Earth’s geophysical
vulnerabilities. The work establishes the theoretical groundwork for a new generation of predictive
systems—GeoPredict— capable of early warning of earthquakes and other large-scale geophysical
processes. By combining quantum entanglement with subquantum synchronization and planetary
oscillatory patterns, this model offers a scientifically plausible path to real-time, high-fidelity monitoring
of Earth’s dynamic equilibrium.
KEYWORDS
subquantum mechanics, infobitic logic, oscillatory quantum computing, entanglement, resonance nodes,
planetary alignments, geophysical vulnerability, GeoPredict, TQC/NMSI.
1. INTRODUCTION
The TQC/NMSI (Twin Quantum Computing – New Subquantum InfoBitic Mechanics)
framework arises as a response to fundamental limitations within the Standard Model and
classical interpretations of space, time, and quantum behavior. While mainstream quantum
mechanics deals with probabilistic wavefunctions and decoherence, it lacks a unifying substrate
that could explain coherence, entanglement, and gravity in a single framework. TQC/NMSI
proposes such a substrate—based not on particles or fields alone, but on synchronized oscillatory
logic and subquantum ‚infobits’ forming an informational vacuum.
This subquantum informational field governs all known interactions, not as isolated effects but
as oscillatory responses to changes in systemic phase equilibrium. Coherence is no longer a
mysterious consequence of quantum isolation, but rather a manifestation of rhythmic, resonant
alignment between oscillatory systems embedded in a logic-based vacuum. This article outlines
the conceptual foundations for this approach and proposes an architecture of computation and
planetary feedback based on oscillatory entanglement and logical resonance.

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2. RELATED WORK
The exploration of subquantum dynamics has remained largely speculative in mainstream
physics, with notable exceptions such as David Bohm’s pilot-wave theory, which introduced a
non-local hidden variable model to explain quantum coherence. Similarly, stochastic
electrodynamics and certain approaches in quantum gravity have postulated a more fundamental
substructure underlying quantum phenomena, yet none has successfully unified the quantum,
relativistic, and informational frameworks into a coherent system.
In the realm of quantum computing, conventional architectures rely heavily on qubit
superposition and fragile entanglement that are sensitive to decoherence. Recent proposals
involving topological qubits, quantum error correction, and time crystals reflect the growing
awareness that oscillatory coherence may be essential for
robust quantum computation. However, these innovations do not address the foundational
informational substrate from which coherence emerges.
TQC/NMSI distinguishes itself by grounding coherence, entanglement, and nonlocality in a
structured oscillatory logic layer beneath standard quantum mechanics. This perspective finds
indirect support in biological oscillatory systems, coherent vibrational modes in condensed
matter, and the phase synchronization observed in astrophysical plasmas and atmospheric
dynamics.
No existing paradigm has yet unified planetary-scale oscillations with subquantum logic as a
computational mechanism. This paper builds upon a variety of such phenomena—
meteorological, geophysical, and cosmological—to construct a theory of natural system
computing driven by resonance and logic, not brute-force computation. The work extends these
insights to propose that tornadoes, magnetic storms, planetary alignments, and quantum
entanglement may all be emergent manifestations of the same underlying informational
oscillatory field.
3. THEORY / PROPOSED MODEL
The TQC/NMSI architecture (Twin Quantum Computing / New Subquantum InfoBitic
Mechanics) proposes that the universe operates as an integrated computational system, based not
on classical logic gates or probabilistic quantum states, but on coherent oscillatory nodes—
termed CLOs (Coherent Logical Oscillators)—that resonate within an infobitic subquantum
field.
This field, composed of infobits, is not energetic in nature but logical-oscillatory, governed by
synchronization, phase alignment, and harmonic coherence. Information is not transmitted by
carriers but emerges from local oscillatory entanglement patterns, analogous to standing waves
in a resonance chamber.
3.1.CLO Units and Logical Structures
Each CLO is an autonomous node capable of both computation and phase synchronization with
neighboring nodes. The state of a CLO is determined by its oscillatory phase, amplitude, and
modulation pattern. In clusters, CLOs form resonant computation networks, capable of logic
synthesis and systemic feedback.

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These networks can naturally align with environmental patterns—geological
formations, biological structures, planetary fields—resulting in hybrid computational
phenomena, where logic and matter co-evolve.
3.2. Oscillatory Logic Instead of Binary Gates
Unlike classical Turing logic, which encodes information as discrete bits (0 or 1), oscillatory
logic encodes states in phase, frequency, and resonance relations. The result is a system capable
of analog-digital hybrid computation, resilient to perturbation due to its harmonized structure.
This model allows parallel computation across spatially separated CLOs, mimicking quantum
non-locality but with stable oscillatory coherence, not probabilistic collapse.
3.3. Planetary Oscillatory Computing and Logical Network
At the planetary scale, the TQC/NMSI model postulates that Earth itself acts as a coherent
oscillatory processor, embedded within a hierarchical structure of logical resonance. Localized
nodes of coherence, termed Coherent Logical Oscillators (CLOs), appear in various
atmospheric, geophysical, or constructed forms—ranging from tornado vortices to ancient stone
complexes and modern resonant architecture.
In this context, tornadoes are interpreted as temporary, mobile CLOs formed in regions lacking
stable geographical resonance points such as mountain peaks. Their emergence serves a
computational and diagnostic function: they probe environmental parameters and transmit data to
the planetary oscillatory core through subquantum phase alignment.
These nodes are not chaotic byproducts of thermodynamic instability, but instead structured,
goal-oriented phenomena within a broader logic system.
The Earth’s resonant shell, composed of permanent and temporary CLOs, creates a planetary
computation network where synchronization, not centralization, governs logical operations.
Each CLO resonates with specific frequencies based on its composition, altitude, geometry, and
interaction with solar, lunar, and cosmic oscillators.
Evidence for such coordination emerges from the geometric regularity of supercell formations,
lenticular clouds, aligned seismic responses, and the harmonic recurrence of extreme weather in
predictable nodal paths. Furthermore, ancient megalithic structures appear to be intentionally
aligned with planetary energetic lines—possibly to maintain or stabilize regional resonance for
climate or communication coherence.
Thus, planetary oscillatory computing emerges as an intentional subsystem of a broader
cosmological logic field, one that continuously interacts with solar, galactic, and even inter-
universal inputs through frequency-phase matching, not energy exchange.
3.4. Temporal Relativity and Oscillatory Frequency
Within the TQC/NMSI framework, time is not an absolute linear dimension, nor merely a
relativistic function of speed and gravity as in Einsteinian theory, but a function of oscillatory
frequencywithin a given subquantum system. The rate at which a CLO or ensemble of CLOs
oscillates defines its subjective temporal flow.

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This interpretation introduces the concept of programmable time—an entity’s perceived
duration and internal causality sequence depend on the frequency at which it resonates in the
subquantum field. Higher-frequency systems experience compressed or accelerated time, while
lower-frequency systems unfold subjective time more slowly, even if both are synchronized by
a global logic rhythm.
This insight explains:
• Why subatomic particles decay at different rates in different environments.
• Why gravitational anomalies alter subjective time without changing the nature of
physical events.
• Why biological processes (aging, memory formation, dream-state duration) vary
disproportionately under different electromagnetic or geophysical resonance
conditions.
In planetary computing, tornadoes, being high-frequency dynamic CLOs, may operate at
compressed subjective time rates, performing rapid environmental assessments and
transmitting massive volumes of structured data over short durations.
Furthermore, the Sun itself—as shown in solar imaging time-lapses—manifests oscillatory
plasma loops and pulsing activity resembling biological cycles, suggesting that stars may
experience and modulate time as a function of their oscillatory core dynamics, not purely as
thermonuclear clocks.
Thus, temporal relativity in the TQC/NMSI model is inherently oscillatory, local, and
programmable, opening possibilities for artificial systems to experience or manipulate time by
tuning their subquantum resonance.
4. RESULTS / IMPLICATIONS / APPLICATIONS
The TQC/NMSI framework yields a rich spectrum of conceptual and technological implications
across multiple scientific domains, many of which redefine traditional boundaries between
physics, computing, and planetary science.
4.1. Earth as a Logical Processor
The model implies that Earth is not a passive object within gravitational equilibrium, but an
active computational entity, maintaining dynamic systemic resonance through distributed
CLOs. This computational capacity enables:
• Global coherence in climate patterns,
• Synchronization of biospheric cycles,
• Natural detection and anticipation of geophysical anomalies, such as earthquakes.
Systems like GeoPredict, built on TQC/NMSI, could detect pre-seismic resonance phase shifts
before traditional mechanical or electromagnetic signals are measurable.

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4.2.Atmospheric Structures as Logical Nodes
Phenomena like tornadoes, lenticular clouds, and supercells are reinterpreted as transient,
intelligent data-gathering processes. These formations emerge when stable nodes are lacking,
particularly in flat regions where natural resonance geometry is weak.
Such CLOs serve:
• As diagnostic oscillators,
• As communication interfaces between Earth and solar-logical cycles
• To reconfigure regional atmospheric equilibrium after high entropy events.
4.3. Artificial CLOs in Architecture and Technology
Ancient sites (e.g., pyramids, Stonehenge, Tibetan stupas) and some modern architectural
complexes inadvertently or intentionally act as amplifiers of resonance. Understanding this
principle could inspire conscious architectural design, with buildings as integrated oscillatory
modules, enhancing:
• Environmental feedback,
• Biologic synchronization (e.g., hospitals),
• Communication with planetary rhythms.
4.4. Next-Generation Computing
TQC/NMSI opens a path to ternary quantum computing via entangled oscillators embedded in
structured materials like endohedral metallo-fullerenes (EMFs). These systems:
• Do not require cryogenics,
• Do not collapse probabilistically,
• Operate continuously via subquantum harmonic resonance.
Their architecture enables instantaneous data transfer through oscillatory synchronization,
offering a paradigm shift in communication speed and scale—beyond light speed as a limiting
metric, since no physical transfer occurs.
5. CONCLUSION AND FUTURE WORK
This work introduces the TQC/NMSI paradigmas a unifying theory that reinterprets
fundamental principles of physics, computation, and planetary behavior through the lens of
subquantum oscillatory logic. The model challenges conventional frameworks by proposing
that:
• Information precedes energy, and that reality is structured around coherent infobitic
oscillations.
• Time is programmable, determined by resonance frequency and not fixed by mass or
velocity.
• Natural phenomena such as tornadoes or solar activity are not chaotic side effects
but logical responses in a planetary-scale computational framework.
• Biological and non-biological life are both emergent properties of synchronized
oscillatory systems, suggesting a broader definition of consciousness and coherence in
the universe.

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The theory also reframes computing: not as manipulation of symbols by deterministic logic, but
as emergent behavior in harmonic systems, offering a viable blueprint for Twin Quantum
Computing (TQC)—robust, scalable, and capable of interacting with planetary and cosmic
information flows.
5.1. Future Directions
To validate and develop the TQC/NMSI system further, several experimental and engineering
paths are proposed:
• Constructing controlled arrays of artificial CLOs using resonant architectural
structures.
• Monitoring geophysical oscillations with subquantum sensitivity via distributed sensor
networks aligned with planetary resonance paths.
• Exploring advanced materials such as EMF-based logical molecules for information
processing without collapse.
• Implementing real-time planetary feedback systems (GeoPredict) for early-warning
detection based on CLO oscillatory phase shifts.
Ultimately, the TQC/NMSI framework aspires not only to expand scientific horizons but to offer
a harmonious integration between human intelligence and planetary logic— a bridge
between conscious computation and the living universe.
ACKNOWLEDGMENTS
The author would like to thank all contributors to the early conceptual development of
TQC/NMSI theory, as well as the editors and reviewers of previous articles whose feedback
helped shape the direction of this research. Special recognition goes to the open-source and
academic communities whose dialogue and data sharing have made such cross-disciplinary
innovation possible.
This work received no specific funding from any public, commercial, or not-for-profit funding
agency.
REFERENCES
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Journals/Research%20Papers/View/10145
[3] Lazarev, S. V. (2025). Tornado as a Cosmic Message: Logical Epilogue in the Planetary TQC
Network. General Science Journal. https://www.gsjournal.net/Science-
Journals/Research%20Papers/View/101423.Bohm, D. (1952). A Suggested Interpretation of the
Quantum Theory in Terms of “Hidden” Variables. I & II. Physical Review, 85(2), 166–193.
[4] Penrose, R. (1994). Shadows of the Mind: A Search for the Missing Science of Consciousness.
Oxford University Press.
[5] Hameroff, S., & Penrose, R. (2014). Consciousness in the universe: A review of the ‘Orch OR’
theory. Physics of Life Reviews, 11(1), 39–78.
[6] Fröhlich, H. (1968). Long-range coherence and energy storage in biological systems. International
Journal of Quantum Chemistry, 2(5), 641–649.
[7] Montagnier, L., et al. (2011). DNA waves and water. Journal of Physics: Conference Series, 306(1),
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