Gravitational Field Measurements

This paper presents a first-principles, energy-driven method for calculating gravitational fields, eliminating mass-based assumptions to achieve faster, more precise gravitational modeling. Traditional methods rely on indirect mass estimations, which introduce uncertainties—particularly for exoplanets and celestial bodies with unknown internal structures. By reformulating gravity through direct energy interactions and stress-energy tensor dynamics, this approach delivers highly accurate results with greater efficiency.Key advancements in this work include:Direct Field Energy Redistribution – a method that calculates gravitational fields without relying on mass as an input variable.Rotational & Frame-Dragging Corrections – incorporating relativistic effects to improve accuracy for high-spin celestial bodies.Tidal Stress Dynamics – refining gravitational models for exoplanets under extreme stellar forces.This computationally efficient approach has been tested across celestial bodies and has demonstrated alignment with observed gravitational structures, as detailed in the supporting document. The framework offers practical applications in exoplanet characterization, celestial mechanics, and high-precision astrophysical modeling, making it relevant for missions such as JWST, PLATO, and TESS.As the first publication within the PAN Framework, this work established the foundation for my later research into gravitational structure and energy flow at galactic scales, which will be explored in upcoming publications. The insights gained from this study also played a role in refining the PAN Equation, demonstrating its ability to unify physics within a single mathematical structure.If this approach interests you, I encourage you to explore my related publications:New Foundation for Understanding Reality – the core theoretical framework behind this work.Introduction to Q-Epsilon – a structured energy framework eliminating probability in quantum mechanics.UMEC – Non-Iterative Computation – an advanced mathematical method relevant to high-speed physics calculations.This paper is not just a theoretical exercise—it introduces a practical, validated method for gravitational field calculations, opening new avenues for astrophysics and planetary science. I welcome engagement, feedback, and collaboration as the PAN Framework continues to evolve.