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| Médium: | Recurso digital |
| Jazyk: | angličtina |
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Zenodo
2026
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| On-line přístup: | https://doi.org/10.5281/zenodo.20139124 |
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- <div> <h2>Monolit (M) Paper 2: Numerical Synthesis of Projective Dynamics —A Linear Progression from Unitless Geometry to Spacetime Phenomenology</h2> <p>April 2026</p> <div><strong>Abstract:</strong> This paper constructs a rigorous, strictly linear mechanical bridge between the absolute, unitless kinematics of the <em>Monolit</em> ($\mathfrak{M}$) framework and the dimensionful observations of 4D spacetime. Utilizing the foundational axiomatic tools established in Paper 1, the logic proceeds sequentially: establishing the objective 24D geometry; instituting strict notational isolation; defining Cognitive Relativity and proving the $\Pi_4$ observer constraint; formalizing the $4 \times 24$ matrix projection; deriving mass operationally as kinematic resistance; formalizing the dust-ansatz stress-energy coupling; outlining the entropic gravity framework; establishing invariant accounting rules across the discrete combinatorial phase space; mathematically resolving geometric singularities; and outlining the non-linear logical restoration protocol.</div> <p>This paper constructs a rigorous, strictly linear mechanical bridge between the absolute, unitless kinematics of the <em>Monolit</em> ($\mathfrak{M}$) framework and the dimensionful observations of 4D spacetime. Operating on the postulate that the Universe is fundamentally unitless, this framework defines physical units, conservation laws, and mathematical singularities as emergent artifacts of a projective interface interacting with a static, 24-dimensional Leech lattice ($\Lambda_{24}$).</p> <p>Building upon the axiomatic tools established in Paper 1, this work formalizes the concept of Cognitive Relativity and provides explicit mathematical proofs for the human $\Pi_4$ observer constraint. By modeling the macroscopic observer interface as a $4 \times 24$ projection matrix constrained by the $C\ell_{3,1}(\mathbb{R})$ Clifford algebra, the paper evaluates the geometric consequences of a 6-to-1 coherent summation.</p> <p><strong>Key derivations and formalisms include:</strong></p> <ul> <li><strong>The Combinatorial Limit:</strong> Algebraic proof that the 1771-state phase space limit is the exact mathematical consequence of the $N=4$ projective interface.</li> <li><strong>Mass as Kinematic Resistance:</strong> The operational derivation of mass as the strictly positive geometric variance trapped within the interface kernel, functioning as a topological drag on the fundamental sequence count ($\sigma_\mathfrak{M}$).</li> <li><strong>Entropic Gravity Compatibility:</strong> Formalizing a dust-ansatz stress-energy coupling that proves the 10-component tensorial compatibility of the $\Pi_4$ covariance matrix with the spacetime metric $g_{\mu\nu}$, establishing the geometric requirements for emergent entropic gravity.</li> <li><strong>Singularity Resolution:</strong> Resolving the continuum approximation by redefining mathematical singularities as topological throughput saturation events bounded by the discrete lattice metric $d_{min}=2$.</li> </ul> <p>The paper concludes by establishing a physical restoration protocol and outlining a testable strategic programme, most notably predicting a falsifiable, cumulative non-linear clock drift in next-generation optical lattice clocks resulting from the discrete $\sim 10^{-40}$ s modulation of the 1771-state periodicity.</p> <div><strong>Keywords:</strong> Emergent Spacetime, Leech Lattice, Entropic Gravity, Combinatorics, Projective Geometry, Clifford Algebras.</div> </div>