Articles

A contemporary archive of articles penned with a rational and innovative perspective, bridging the gap from natural to social sciences. Your destination for original research, in-depth analysis, and scholarly articles in physics, philosophy, history, economics, theology, and beyond.

Quantum Fractal Analysis 2 – Lecture Notes

In quantum fractal analysis, potential functions are the extension of classical quantum potential energy with fractal scale dependence. The aim is to model energy resonances at both micro and macro levels by analyzing the probability waves of particles within a fractal space-time structure.

Quantum Fractal Analysis 1 – Lecture Notes

While defined by self-similarity and scale invariance in classical mathematics, the quantum fractal exponential function combines this structure with quantum wave functions, revealing fractal resonance in probability distributions. The side-by-side graphs in the visual show a comparative view of the deterministic repetition of the classical fractal exponential function and the wave-particle interactive, luminous fractal structure of its quantum version.

Fractal Analysis – 2 Lecture Notes

7- Let’s expand the fractal analysis chain with fractal probability distributions (𝑷𝒇). This is a motif-repeating, multi-scale version of classical probability theory and provides entirely new definitions for uncertainty, risk, and variational systems. Classical Probability Distribution The classical probability density for a random variable 𝑋: 𝑃(𝑥) ≥ 0, ∫-∞∞ 𝑃(𝑥) 𝑑𝑥 = 1 It is a

Fractal-Mechanical Classification of Elements

Viewing elements as fractals makes it possible to reclassify them according to mechanical principles. Because in the fractal approach, every structure is defined by motifs that repeat themselves on both micro and macro scales. Mechanical principles, on the other hand, allow these motifs to be classified according to their relationships of equilibrium, force, energy transfer, and resonance.

Fractal Analysis – 1 Lecture Notes

Classical analysis treats nature as an instantaneous cross-section; it takes a “photograph” of nature with fixed parameters, stationary equations, and single-scale processes. Fractal analysis, however, treats nature within process, through interactions between scales, resonance, and feedback loops—essentially, it takes a video of nature.