The Heisenberg uncertainty principle has been regarded as a fundamental axiom of nature since its formulation. In this paper, within the SGCU (Cosmic Topology) framework, we demonstrate that quantum uncertainty is not a fundamental law, but a statistical emergence of quantum fluctuations of the normal vibration of spatial layers (the -field). Starting from the SGCU action, we rigorously derive how vacuum fluctuations of the -field stochastically drive the center-of-mass motion of the electron soliton, and via the Fokker--Planck equation and the Madelung transformation, we equivalently obtain the Schrödinger equation and the Heisenberg uncertainty relation. The effective Planck constant is uniquely determined by the mass of the particle m_ 47 MeV, the coupling g ₄₄, and the spatial stiffness, yielding a calculated value of ₄₅₅ 1. 4, in good agreement with the observed. The 47 MeV resonance is not merely a new particle beyond the Standard Model, but the geometric entity underlying the origin of quantum mechanics---it is the "calibrator" of the existing quantum world. This conclusion reduces quantum mechanics to the classical statistical mechanics of spatial overlap geometry.
Yida Huo (Sun,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: