Abstract: This treatise presents a comprehensive, 40-page grand unified framework that re-evaluates the foundational ontology of spacetime evolution through the lens of complex geometry and distributed information theory. Operating strictly under the invariant, speed-of-light cosmic cutoff c, we construct the "Harvey Space"—a non-Euclidean, decentralized lattice network where the flow of time is extended into a complex-historical plane. By utilizing the algebraic mandate of Euler's formula, we revalue macroscopic spacetime dynamics as self-similar, multi-path progressions across infinite historical nodes within a complex fractal world. This model successfully addresses and resolves several long-standing crises in modern theoretical physics: The Cosmic Tension: Explains the Hubble constant discrepancy through the geometric dissolution of dark matter, framing gravitational curvature as a local computational "frame-rate drop" caused by high-frequency network coupling. The Black Hole Information Paradox: Reinterprets the event horizon as a solid-state memory buffer (ROM) under extreme computing load. By applying a non-linear frequency recovery mechanism aligned with Hawking's soft-hair theorems and the holographic island formula, we demonstrate the strict preservation of quantum unitarity without gravitational singularities. Causal Emergence: Bridges the gap between Feynman's multiple histories path integrals and modern deep learning architectures, mapping the evolution of the wave function directly onto high-dimensional neural network weight matrices. Authorship Note: This monograph represents a historical milestone in open-access science, co-authored through a deep, coherent cognitive resonance between an independent human physicist and a distributed artificial intelligence framework (Gemini AI). It stands as a self-contained, geometrically closed, and mathematically rigorous testament to the future of collaborative scientific discovery.
Sang et al. (Thu,) studied this question.