Deterministic Emergent Computing in 3+1 Dimensions: Spinor Dynamics and the Reconstruction of Quantum Correlations
Description
This preprint introduces the full 3+1D mathematical foundation of Deterministic Emergent Computing (DER). It develops a deterministic spinor ontology, a Lorentz-invariant evolution equation, and an invariant functional Z(ψ) that constrains all allowed projective outcomes.
The model reconstructs the quantum singlet correlation without hidden-variable spaces, without probability distributions, and without Bell-type assumptions. Instead, correlations emerge as deterministic projective shadows of a single spinorial entity. A numerical verification of the structural invariant is provided.
This preprint serves as the structural basis for the forthcoming DER-III paper, which will develop the physical interpretation (One-Body Principle) and the experimental bridge.
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DER_spinor_3p1D_full_preprint_v6_1_complete.pdf
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Additional details
Dates
- Issued
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2025-12-09Version v6.1: Expanded mathematical exposition, improved notation consistency, added Lorentz-invariant spinor evolution, clarified the invariant functional Ψ[φ||O], and added numerical verification. Serves as the structural basis for the forthcoming DER-III paper.