What question did this study set out to answer?

The primary aim is to develop a mathematical model that resolves gravitational singularities in the universe.

February 13, 2026Open Access

Anadihilo Dynamics: The Final Resolution of the 3-Body Problem and the Dagar (Dg) Scale of Mass Intensity

Key Points

The primary aim is to develop a mathematical model that resolves gravitational singularities in the universe.
Implemented the Dagar Scale as a new metric for mass intensity.
Introduced the Axiom of Normalization to address the 0/0 identity issue.
Integrated a normalization factor in the governing equation to avoid infinite force values.
Simulations of the three-body problem produced deterministic trajectories.
Findings suggest planetary interactions follow specific rules instead of chaotic behavior.

Abstract

Anadihilo Dynamics: The Final Resolution of the 3-Body Problem Core Objective: To establish a crash-proof mathematical model of the manifest universe by resolving gravitational singularities. Key Methodologies: The Dagar (Dg) Scale: A new metric for mass intensity defined as resistance on a discrete informational grid. Axiom of Normalization: A formal proof resolving the 0/0 identity at the systemic boundary (n). Singularity Fix (): Integration of a normalization factor (= 1/ (Pⱼ + Pₖ) ) within the governing acceleration equation to prevent infinite force values. Results: The simulation of the Pythagorean 3-body problem using this framework yields deterministic trajectories with finite systemic peaks. This proves that planetary interactions are informational routines governed by specific resolution limits rather than continuous chaotic variables. Data Availability: Full numerical logs and simulation source code are archived at DOI: 10. 5281/zenodo. 18604056.

Anadihilo Dynamics: The Final Resolution of the 3-Body Problem and the Dagar (Dg) Scale of Mass Intensity

Key Points

Abstract

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