What question did this study set out to answer?

To establish a stabilized framework for Ibaguner Fractal Operator dynamics, replacing divergent behaviors with bounded compression.

February 11, 2026Open Access

Ibaguner Fractal Operator (IFO) Compression-Collapse Dynamics and the Omega Attractor Principle

Key Points

To establish a stabilized framework for Ibaguner Fractal Operator dynamics, replacing divergent behaviors with bounded compression.
Developed an Ibaguner Fractal Operator compression-collapse framework.
Defined the IFO Omega state and proved its properties.
Conducted numerical parameter sweeps across high-dimensional fields.
Demonstrated finite complex collapse states instead of singular divergences.
Confirmed logarithmic scaling and phase stability across tested parameters.
Established the Omega attractor principle for stabilized dynamics.

Abstract

We formalize a stabilized Ibaguner Fractal Operator (IFO) compression-collapse framework in which classical divergent exponential-hyperbolic cascades are replaced by bounded nonlinear compression and logarithmic compactification. The resulting operator produces finite complex collapse states instead of singular divergence. We define the IFO Omega state as a normalized asymptotic limit and prove existence, boundedness, and magnitude-phase separation laws. Numerical parameter sweeps confirm logarithmic scaling, phase stability, and compression plateaus across high-dimensional fields. This establishes an Omega attractor principle for stabilized IFO dynamics.

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Cite This Study

SİNAN İBAGÜNER (Thu,) studied this question.

synapsesocial.com/papers/698c1bb8267fb587c655d8fb https://doi.org/https://doi.org/10.13140/rg.2.2.24898.64960

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