This paper introduces the framework of Status-Relational Entropy (SRE) Dynamics, proposing a fundamental shift in physics by treating spacetime and energy as derivative constructs of causal measurement. The theory is built on a single underlying parameter defined as the Minimum Observational Step (L-min), which represents the smallest unit of logical triggering. Under this framework, the electron is redefined not as a material object, but as an irreducible N-step causal loop with a dual-phase topology. By analyzing the frequency and counting ratios of this logical loop during the measurement process, the paper demonstrates that fundamental physical properties are necessary manifestations of this structure. Key derivations include: Rest mass is explained as the computational overhead required to process the internal steps of the loop. Unit charge is identified as a constant logical offset or step-size bias generated by the electron node. Spin-1/2 is shown to be a mathematical requirement of the double-counting cycle within the loops topology. The uncertainty principle is interpreted as sampling noise inherent to the discrete resolution of the minimum observational step. The research concludes that physical reality acts as a rendered output of global causal protocols, simplifying complex physical constants into topological counting relationships.
Yue Lu (Wed,) studied this question.