This article provides an orientational framework connecting a series of previously published research papers on the mechanism of gravitational motion, temporal structure, galactic dynamics, gravitational lensing, and quantum probability. It is not intended as a standalone theory, textbook, or comprehensive review. Instead, it serves as a conceptual and empirical map that situates individual results within a coherent research trajectory developed over several years. The central guiding question of this work is not how gravitational phenomena are mathematically described, but how they are physically realized. Throughout the article, gravity is approached operationally, beginning from what is actually measured in experiments and observations: clock rates, trajectories, stability of motion, signal delays, and long-term coherence. From this perspective, gravity appears not as a local interaction or force, but as a temporally organized, global structure that constrains which paths of motion can be realized. The text traces how this viewpoint applies consistently across different regimes, including local acceleration, galactic rotation curves, gravitational lensing, dissociative galaxy cluster collisions, limits of realizability, quantum probability, and the boundary regime represented by light. Standard Newtonian and relativistic results are recovered as limiting cases, while no new particles, interactions, or modifications of fundamental equations are introduced. Mathematical derivations, empirical analyses, and detailed tests are deliberately not reproduced here. These are developed in the author’s individual research articles, which are referenced throughout and listed explicitly at the end. The present article is therefore best read as an entry point and guide to the broader research program, rather than as a summary of results or a formal theoretical proposal.