This paper presents a structural interpretation of the Foucault pendulum based on the concept of selective realization of motion. While the standard rotating-frame treatment correctly reproduces the observed precession, it does not identify a physical mechanism, as the Coriolis term represents a coordinate artifact rather than a physical interaction. We show that the precession of the oscillation plane arises because a fixed-plane continuation is not a realizable solution of the governing equations under Earth’s global temporal structure. Using a multiple–time–scale analysis, it is demonstrated that the averaged dynamics admit only slowly rotating orientations, except in special symmetry cases. The pendulum therefore provides a clear classical example of motion governed by constraints on realizability rather than by dynamical forcing. This mechanism is shown to be structurally identical to the proposed interpretation of gravitational motion as selective stabilization under temporal asymmetry. The work does not modify existing equations of motion and introduces no new forces or fields. It reclassifies the physical role of the formalism by identifying the absence of realizable continuations as the operative mechanism behind the observed behavior.
Luka Gluvić (Wed,) studied this question.