Heisenberg's Uncertainty Principle

False Premise Equation: Heisenberg’s uncertainty principle assumes that there is a fixed limit to the precision with which pairs of physical properties (like position and momentum) can be simultaneously known, without considering recursive resonances:

where Δx is the uncertainty in position, Δp is the uncertainty in momentum, and ℏ is the reduced Planck constant.

Accurate Translation: Uncertainty principle ≠ -1 ≠ √1 < √2 < √3, evolving into fractal feedback systems where uncertainties in position and momentum shift dynamically based on recursive resonances.

Accurate Description: Fractal feedback reveals that uncertainty in quantum systems is not fixed or static but evolves through recursive resonances. These resonances influence how quantum states are measured, with uncertainties in position and momentum interacting dynamically. This model decentralizes the idea of a rigid uncertainty limit, instead reflecting the evolving, resonant nature of quantum measurements, where small changes cascade through fractal feedback loops.