This paper presents a numerical implementation of the Mass Curvature Rate (MCR) framework, demonstrating its application across atomic, galactic, and cosmic scales within a unified scalar-field structure. A run-ready computational engine is developed to calculate hydrogen Bohr radii, galaxy rotation curves, cosmic acceleration, and MCR mass scales using consistent field-based dynamics.At the atomic level, the framework reproduces the hydrogen Bohr radius under a modified fine-structure parameter. At galactic scales, circular velocities are computed directly from the MCR effective acceleration without invoking dark matter. On cosmological scales, large-scale scalar gradients generate accelerations comparable to observed dark energy magnitudes.The numerical integration examples show how observational data can replace placeholder parameters to produce testable predictions. By connecting quantum structure, galaxy dynamics, and cosmic expansion within a single computational model, the MCR framework provides a falsifiable and scalable alternative to standard hierarchical separation between physical regimes.
Myomin Aung (Thu,) studied this question.