We propose Origin Geometry (OG), a foundational geometric framework in which spacetime, quantum mechanics, gravitation, matter, and cosmological structure emerge from a discrete, elastically connected geometric substrate rather than being assumed as primitive ingredients of physical reality. Within this framework, Lorentz invariance, quantum dynamics, effective gravitational behavior, and large-scale cosmological organization arise as coarse-grained manifestations of a deeper non-periodic higher-dimensional geometry characterized by topological organization, elastic response, and multiscale screening. OG establishes a strict distinction between fundamental ontology and effective physical description. Quantum mechanics and general relativity are therefore interpreted not as foundational axioms, but as emergent large-scale theories that arise from the collective behavior of an underlying geometric network. Matter is identified with stabilized topological excitations of the substrate, while physical constants emerge as geometric and topological invariants associated with boundary–bulk relations. A central feature of the framework is the mechanism of Topological Camouflage, through which microscopic discreteness, anisotropy, and higher-dimensional connectivity become effectively hidden at observable scales, allowing locality, relativistic symmetry, and quantum nonlocal correlations to coexist within a unified geometric description. The objective of the present work is not to provide a complete replacement of the Standard Model, nor to claim experimental confirmation. Instead, this paper establishes a logically closed, internally consistent, and explicitly falsifiable ontological foundation upon which future dynamical formulations, numerical simulations, and phenomenological investigations may be constructed. Explicit failure modes and falsifiability criteria are presented throughout the work. The framework is therefore introduced as a scientific proposal subject to future theoretical development and empirical examination rather than as a completed theoretical system. The present paper is intentionally pre-dynamical in scope. It does not attempt precision cosmological modeling, detailed particle phenomenology, or quantitative fitting of observational data. Its purpose is to establish the conceptual and geometric foundation from which such developments may subsequently emerge.
The Duy Tan Truong (Thu,) studied this question.