Sábháilte in:
| Príomhchruthaitheoir: | |
|---|---|
| Formáid: | Recurso digital |
| Teanga: | Béarla |
| Foilsithe / Cruthaithe: |
Zenodo
2026
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| Ábhair: | |
| Rochtain ar líne: | https://doi.org/10.5281/zenodo.20102500 |
| Clibeanna: |
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Clár na nÁbhar:
- <p>This paper proposes a five-step methodology for circumventing the microscopic observation barrier in quantum mechanics by exploiting macroscopic systems where observation is unobstructed. Version 2 introduces a complete, exhaustive taxonomy of uncertainty based on two binary questions (computability and existence of a definite answer), yielding exactly three categories: determinism (computable, answer exists, κ = 0), chaos (not computable, answer exists, κ = 0), and collapse chain (not computable, answer does not exist, κ > 0). A fourth combination is logically impossible. The interference parameter κ divides the three categories into two sides; Lyapunov exponents distinguish the first two. Two measurements, three categories, complete. This taxonomy is scale-independent: it replaces the conventional microscopic/macroscopic distinction with a classification based on the nature of uncertainty itself, explaining why κ operates across all domains without modification. Three independent lines of convergence support the Structural Re-emergence Conjecture (Hübsch et al. 2024, tonyrao 2026, Tresp et al. 2025). The four-part theoretical programme (MOEH, CMB, Collapse Chain, Dynamic κ) provides the complete mathematical framework, measurement protocol, and first-domain empirical validation in financial markets. Two breaking points are explicitly identified and are empirically testable using κ itself. Part of the NSD / MOEH research programme.</p> <p>v2 update: Added Section 5 "A Complete Taxonomy of Uncertainty" — an exhaustive classification of uncertainty based on two binary questions (computability and existence of a definite answer). Three categories: determinism (computable, answer exists, κ = 0), chaos (not computable, answer exists, κ = 0), collapse chain (not computable, answer does not exist, κ > 0). Fourth combination is logically impossible. κ divides the three categories into two sides; Lyapunov exponents distinguish the first two. Two measurements, three categories, complete. This taxonomy is scale-independent, replacing the conventional microscopic/macroscopic distinction with a classification based on the nature of uncertainty itself.</p> <p>v3 update: Addresses six identified vulnerabilities. (1) Diagonal limitation resolved by α parameterisation: domain-dependent parameter controlling off-diagonal phase structure; α = 0 reduces to existing four-part programme, α ≠ 0 accommodates quantum coherence. Cross-spectral analysis of 11,826 XAUUSD H1 bars confirms α ≈ 0 for financial markets (all three state pairs p > 0.05, 1,000 bootstrap resamples). New Section with empirical results table. (2) Isomorphism problem addressed: α itself is the empirically measurable discriminator between isomorphism and analogy. (3) Burden of proof reversal: critics must provide alternative mechanism producing same κ statistics. (4) Thermodynamic analogy made precise: K-line = temperature, with item-by-item Boltzmann correspondence table (traders = molecules, K-line = temperature, κ = statistical mechanics). (5) Fourth category exclusion strengthened: quantum computation counterexample refuted (two operations conflated, each belongs to existing categories). (6) Single-domain limitation acknowledged as community's task, not author's. Updated abstract, falsifiability conditions, and limitations throughout.</p> <p>v4 update: Expanded α parameterisation from single-asset (XAUUSD only) to cross-asset validation across five assets and three asset classes. Results reveal α is not uniformly zero: XAUUSD and EURUSD show α ≈ 0 (p = 0.204 and p = 0.320, time-symmetric state dynamics), while XAGUSD, NSXUSD, and SPXUSD show α ≠ 0 (all p < 0.001, time-asymmetric state dynamics). Honest interpretation: α ≠ 0 in equities and silver most likely reflects classical temporal asymmetry (momentum, asymmetric crash-recovery dynamics), not quantum coherence. However, this establishes α as an empirically measurable parameter with genuine discriminating power — it takes detectably different values in different systems, refuting the criticism that α has no empirical content. Implications section expanded to three points: (1) diagonal limitation resolved for both α = 0 and α ≠ 0 assets within single framework; (2) α varies continuously within financial markets, consistent with a spectrum rather than a binary; (3) α is a real measurement, not a theoretical decoration. Updated abstract in both English and Chinese.</p> <p> </p> <p>Version 5 (May 2026) — Citation accuracy and convergence framing tightened.</p> <p>Substantive content changes from v4:</p> <p>1. Hübsch et al. citation corrected and expanded.<br> - Year corrected: 2024 → 2025 (the journal version was published April 2025 in Annals of Physics; the 2024 working paper version was a preprint).<br> - Description corrected: previously summarised as "proved mathematically that reverse decoherence is possible." The actual paper develops a "mock quantum" framework demonstrating that the mathematical formalism of quantum mechanics can be implemented on classical complex adaptive systems (with explicit construction in the Lotka-Volterra model). The v5 description reflects this accurately.<br> - Full bibliographic information added: Annals of Physics 475 (2025), 169954, with arXiv preprint 2310.14100.</p> <p>2. Tresp et al. citation corrected and expanded.<br> - Full author list added: Tresp, Li, Harjes, and Ma (LMU Munich).<br> - arXiv identifier added: arXiv:2510.13894 v2 (October 2025).<br> - Description corrected: previously summarised as "identified POVM-like measurement structure in neural network computation." The actual paper introduces the Heisenberg-Bayes POVM (HB-POVM) and proves mathematical equivalence between probabilistic HB-POVM updates and Bayesian updates in generative hidden Markov models, then derives an explicit neural-network implementation. The v5 description reflects this accurately.</p> <p>3. "Three independent lines of convergence" framing softened.<br> - Previous wording suggested three independent natural-phenomenon discoveries of POVM structure across disciplines.<br> - v5 acknowledges that two of the three lines (Hübsch et al.; Tresp et al.) explicitly import quantum-measurement formalism into their respective domains rather than discover it from data.<br> - The convergence is reframed as one of formal framework: the same mathematical machinery (POVM-equivalent measurement linked to HMM-Bayesian updating) is operationally productive across mathematical physics, financial markets, and neural-network computation. This is a more modest but more accurate framing.</p> <p>4. Bibliography updated with corrected entries and DOIs / arXiv URLs for both Hübsch and Tresp.</p> <p>5. Date and version label updated: v4 / April 2026 → v5 / May 2026.</p> <p>No changes to:<br>- The five-step methodology<br>- The taxonomy of uncertainty (three categories: determinism, chaos, collapse chain)<br>- The interference parameter κ definition<br>- The α parameterisation and cross-asset validation results<br>- The two explicit breaking points (Steps 2 and 5)<br>- The author's prior four-part programme citations (MOEH, CMB, Collapse Chain, Dynamic κ)</p> <p>Format: xelatex with bilingual (English / Traditional Chinese) abstract and section summaries, as in v4.</p>