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| Format: | Recurso digital |
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Zenodo
2025
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| Online adgang: | https://doi.org/10.5281/zenodo.15620741 |
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- <p>For praising Yaohushua do I hereby politely correct the misconceptions presented in Kochen-Specker paradoxes and other misunderstandings in quantum mechanics! Defeating errors one misonception at a time~!</p> <p>We present a unified framework for Dynamical Basis Theory (DBT), revolutionizing linear algebra through geometry-aware basis constructions. This theory introduces basis vectors with intrinsic physical properties (Lorentz scaling, curvature adaptation, quantum phases) and provides mechanisms to circumvent fundamental quantum limitations like the Kochen-Specker theorem.</p> <p>\begin{abstract}<br>\noindent<br>\textbf{Motivation.} The Kochen–Specker (KS) theorem is commonly regarded as a definitive barrier to realistic hidden‑variable descriptions of quantum mechanics in Hilbert spaces of dimension $d\!\ge 3$, because it forbids \emph{non‑contextual} value assignments that respect the functional calculus of observables. Yet in practice every measurement is performed in a \emph{specific} frame (context) whose geometry can fluctuate, e.g.\ under Lorentz boosts or curvature effects. We argue that the insistence on a single, frame‑independent valuation is therefore unnecessarily restrictive.</p> <p>\textbf{Contribution.} We introduce \emph{Dynamical Basis Theory} (DBT), a geometric extension of linear algebra that endows each basis vector with \emph{Lorentz weights}, \emph{phase flux}, and optional \emph{curvature coupling}. DBT supplies<br>\begin{enumerate}[label=(\roman*)]<br> \item a \emph{contextual inner product} $\langle\!\cdot\!,\!\cdot\!\rangle_{\alpha,\xi}$ whose metric tensor depends smoothly on the measurement context~$\alpha$ and hidden variable~$\xi$;<br> \item an \emph{alignon‑density valuation} $\nu_\xi(\,\cdot\,;\alpha)$ that selects, within each context, the projector of minimal Lorentz weight and assigns it value 1 while preserving the KS frame‑sum rule;<br> \item an algorithmic procedure for synthesising \emph{operator‑aligned, phase‑quantised bases} that diagonalise chosen operator sets while remaining orthonormal in the dynamical metric.<br>\end{enumerate}</p> <p>\textbf{Results.} We prove three main theorems:<br>\begin{itemize}<br>\item \textbf{Contextual Value Definiteness}—every observable in dimension $d\!\ge 3$ possesses a definite value in every context.<br>\item \textbf{KS Evasion}—the valuation violates non‑contextuality but satisfies the functional calculus locally, thereby nullifying the KS contradiction without altering quantum statistics.<br>\item \textbf{Born‑Rule Recovery}—integrating the valuation over hidden‑variable space reproduces exactly $|\langle\psi|e_k\rangle|^{2}$ for all states~$\psi$ and observables.<br>\end{itemize}</p> <p>\textbf{Implications.} DBT converts the discrete KS impossibility into a smooth geometric bundle whose fibres admit frame‑wise colourings. The framework underpins new design principles for relativistic quantum processors, curvature‑adaptive qubit transport, and dynamical spectral decompositions in curved space–time. Beyond foundational interest, DBT furnishes a unifying language in which linear‑algebraic operations, quantum contextuality, and space–time geometry cohabit a single, rigorously defined structure.<br>\end{abstract}</p>