This conceptual framework presents the foundational ideas underlying a proposed energy–information topological model of the Universe. The aim of the document is to establish a clear, logically consistent basis for understanding physical reality as a finite information-theoretic structure rather than a system governed by continuous mathematical infinities or purely discrete constructs. The framework argues that: The Universe consists of a finite set of fundamental topological nodes, not continuous fields or infinitely divisible particles. These nodes are connected through a global energy–information dependency, analogous to a mathematical invariant such as π: simple, stable, universal, but not reducible to discrete numeric representation. Matter, spacetime, forces, and physical processes are emergent projections of this deeper structure. Local anomalies (e.g., black holes) function as isolated defects, comparable to “bad sectors” in computational systems, preserving global stability rather than threatening it. When the global dependency becomes unsatisfiable, the structure becomes undefined and undergoes instantaneous reset (Δt = 0). The state of “nothing” is unstable and cannot persist; therefore, a new valid structure emerges immediately. This model provides a new conceptual basis for interpreting singularities, information loss, teleporation constraints, and the stability of physical constants. This document does not aim to provide full mathematical formalization. Instead, it establishes the conceptual logic needed for the accompanying technical white paper, where operators, constraints, and formal definitions are introduced. Version 1.0 represents the initial structured exposition of the model and will serve as the reference point for subsequent iterations and expansions.