This preprint proposes a physical explanation for a long-overlooked empirical anomaly: real-world measurements of circles do not reproduce the mathematical value of π, but instead show a consistent upward bias. Rather than treating these deviations as random measurement imperfections, the paper demonstrates that the bias is systematic and naturally arises if 3D space is a “slack” projection of a higher-dimensional resonant geometry. The work introduces a 4D circular constant π₄D = 3 whose projection into 3D produces the familiar irrational π ≈ 3.14159 and its distorted experimental counterpart. Small-scale measurements of circular objects cluster around (C/D)² ≈ 9.7–9.8, consistent with a projection of the integer value 9 rather than the Euclidean π² ≈ 9.8696. Within the broader Resonance Model developed by the author, π₄D serves as a fundamental calibration constant linking geometry, particle stability, and the SC-envelope structure that underlies gravitation. The hypothesis provides a coherent framework connecting circular geometry, dimensional projection, and physical wave-resonance structure — and suggests concrete experimental paths for testing the deeper geometry of matter and gravity.
Nilsson Henrik (Mon,) studied this question.