This manuscript is a proposal paper specifying an experimentally implementable,pre-registered protocol designed to bridge two layers of the Adaptive Spacetime Ren-dering (ASR) / Informational Relativity program: (i) an observer-local normalizationprinciple (each observer can locally set τ = 1), and (ii) a subsequent extension in whichobserver-node informational dynamics are treated as explicit variables. The proposedtest uses two ultra-precise atomic clocks separated by ≳ 1 km and compared via a sta-bilized time/frequency-transfer link. Clock A (test site) is operated under controlledhuman occupancy and state conditions, while Clock B (control site) is operated under afixed low-activity policy. Five pre-registered scenarios are defined: (S0) 0 participants(baseline), (S1) 10 active, (S2) 100 active, (S3) 10 sleep/rest, (S4) 100 sleep/rest. Theprimary observable is the fractional frequency difference y(t) = (fA(t) − fB (t))/fB (t),analyzed under randomized schedules, blinded condition labels, comprehensive envi-ronmental logging, and explicit falsification criteria. The protocol is constructed to(a) suppress common-mode drift via differential comparison, (b) quantify and penalizeclassical perturbation channels (thermal, magnetic, vibration, RF/EMI, power-quality,link stability), and (c) determine whether any condition-locked residual signatures per-sist beyond a fixed covariate-control model class at a stated sensitivity. The intent isnot to assert a finalized microscopic mapping from “information” to ΦI , but to enablea decisive empirical constraint that can inform (or bound) subsequent observer-nodeextensions.
J. H. Jo (Fri,) studied this question.