Finite-resolution measurement induces topological curvature defects in spacetime

Abstract

We show that regularizing (2+1)-dimensional Minkowski spacetime with a finite-resolution Gaussian probe, analogous to Weyl-Heisenberg (Gabor) signal analysis and related quantization, induces a curved geometry with a topological defect. The regularized metric replaces r2 by r2+σ2 in the angular part, where σ is the resolution scale from the width of the Gaussian probe. The resulting Gaussian curvature integrates to -2π, independently of σ. This curvature defines an effective stress-energy source with universal total energy Eeff=-1/(4G). The limit σ0 leads to distributional Dirac-delta curvature and to appearance of topological defect at the origin. These results show that finite spatial resolution measurement does not merely smooth singularities but can shape spacetime geometry.