English

A Detector-Based Inference Framework for Quantum Theory and Spacetime Geometry

Quantum Physics 2026-04-14 v1

Abstract

We develop a detector-based framework in which quantum theory and spacetime geometry arise within a common inferential structure. Detector states and a detector kernel assign amplitudes to measurement events, allowing quantum theory to be interpreted as weighting hypothetical configurations consistent with observed detector clicks. Using a Gaussian detector model with phase structure, we show that distinguishability induces an information geometry on detector-state space, described by the quantum geometric tensor. A Lorentzian spacetime metric is reconstructed from coupled position and time detector sectors, with both amplitude and phase deformations contributing to geometry. Scalar curvature acquires an operational interpretation as a local deficit of distinguishable outcomes. We construct an effective consistency functional combining detector-deformation cost with a geometric term selected by locality and diffeomorphism invariance. Its stationary configurations yield the Einstein equation, with a stress-energy tensor arising from detector deformations. Vacuum configurations need not be flat, while local deformations provide an operational notion of matter and recover standard field-theoretic behavior in the scalar sector.

Keywords

Cite

@article{arxiv.2604.10349,
  title  = {A Detector-Based Inference Framework for Quantum Theory and Spacetime Geometry},
  author = {Marcello Rotondo},
  journal= {arXiv preprint arXiv:2604.10349},
  year   = {2026}
}
R2 v1 2026-07-01T12:04:35.070Z