Preprint · Release 17
Nuclear Fusion Tokamak with Self Sustaining Resonance
Abstract
This engineering proposal applies resonance and coherence concepts to diagnostics-driven tokamak control. It develops transport proxies, actuator allocation, safety margins, energy-accounting gates, and simulated handoff logic; the architecture remains distinct from demonstrating physical wall-power independence.
Plain-language overview
Research question
Can resonance and coherence concepts inform a diagnostics-driven control architecture for tokamak operation?
Main contribution
- Applies resonance and coherence concepts to diagnostics-driven tokamak control.
- Develops transport proxies, actuator allocation, safety margins, and energy-accounting gates.
- Specifies simulated handoff logic for the control architecture.
Evidence type
Current limitations
The work is an engineering control architecture with simulated logic; it remains distinct from demonstrating physical wall-power independence.
Research assets
- Read & download
- Zenodo record (manuscript and files)
- Research program hub
- geometry_of_resonance — equations, manuscripts, and simulations
Related works
Verification and traceability
This section is generated from the canonical publication traceability registry. Empty fields are reported rather than inferred.
- Claim IDs
- Equation IDs
- SymPy audit
- Lean coverage
- Assumptions
- Formalization
- CONTROL_ARCHITECTURE
- Empirical state
- SIMULATED_LOGIC
- Independent replication
- NONE_RECORDED
- Repositories
Explicit falsifiers
- The controller fails declared confinement, safety, or power-accounting margins under a validated plant model or hardware test.
Open obligations
- Publish controller code, plant assumptions, state variables, actuator model, safety gates, input decks, and independent simulation or experimental validation.
Recommended citation
Reyes, R. J. (April 14, 2026). Nuclear Fusion Tokamak with Self Sustaining Resonance. Zenodo. https://doi.org/10.5281/zenodo.19578185
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Machine-readable identifiers
This landing page provides accessible summaries and citation metadata for an archival preprint. The authoritative manuscript and downloadable files are maintained on the Zenodo DOI record. Wave Confinement Theory is an evolving independent framework; claims should be evaluated according to the derivations, simulations, experiments, data analyses, assumptions, and limitations stated in the paper itself.