The Beginning of Resonance
Quantoniumos began with a clear goal: rethink how operating systems process information.
Instead of relying on static logic and syntax parsing, it treats computation as a structured interaction of waveform patterns and symbolic states.
The result is a hybrid framework that enables geometry-aware memory, signal-based logic, and a new method of transformation—rooted in symbolic structures, not conventional execution models.
What is Quantoniumos?
Why Classical Computing Isn’t Enough
Traditional systems rely on binary logic, static threads, and linear processing.
Quantoniumos breaks that boundary
It replaces bits with symbolic amplitudes, control flow with resonant transformation, and static memory with geometric data encoding—introducing a new logic of structure, vibration, and resonance.
The Symbolic Triad
At the core of Quantoniumos lie three foundational mechanisms that define symbolic processing:
Luis Minier
is an independent researcher and systems developer focused on next-generation computational models.
He is the creator of the Symbolic Resonance Computing framework and the architect behind Quantoniumos, a hybrid operating system built on principles of structured transformation, waveform processing, and geometric memory.
In January 2025, he filed USPTO Patent #63/749,644 to protect the foundational methods underlying the system.
His work challenges conventional boundaries in computing by introducing models that prioritize signal behavior, symbolic mapping, and non-binary logic over traditional abstractions.
Meet the Architect
PROOF OF PARADIGM
Zenodo preprint - https://doi.org/10.5281/zenodo.15126561
Protected under USPTO Provisional Patent Application No. 63/749,644 (filed January 26, 2025) & USPTO Non-Provisional Patent Application No. 19/169,399 (filed April 3, 2025)
QUANTUM RESONANCE DEBUGGING
Real-time diagnostic visualization from the Quantoniumos symbolic engine.
This chart represents internal state transformations mapped across time, frequency, and amplitude—capturing resonance behavior during symbolic execution.
The system identifies critical alignment patterns, waveform interactions, and structural transitions that cannot be seen in traditional debugging models.
This analysis method is unique to the Quantoniumos paradigm and forms part of a protected symbolic transformation process.© 2025 Luis Minier. Quantoniumos is a protected research framework under U.S. Patent Application No. 19/169,309. All content and materials on this site are part of a pending non-provisional patent filing and may not be reproduced or redistributed without permission.