CBHIRT is an informational initial-conditions framework that specifies the informational initial conditions of each FRW cycle, rather than a conventional physical cosmology model. It does not modify general relativity, introduce new matter or energy components, or invoke quantum-field dynamics in the early Universe. Instead, the framework is built from Page-time correlations associated with black-hole evaporation. The quantity ₑ is not an energy density but an informational descriptor encoding the correlation--packing structure of Page-time information. Likewise, H and a (t) are not physical expansion variables; they parametrise the rate and indexing of the mapping from an informational configuration into the FRW representational layer. The relation \ H^2=8 G3ₑ (1-ₑ_{}) \ is therefore an informational constraint, not a dynamical GR equation. It expresses the saturation limit of Page-time correlation packing and prevents a divergent informational precursor without invoking a geometric bounce. Page-time information is assumed to exhibit a universal log-normal structure. When mapped into cosmological modes by the informational kernel K (p k), determined by the information-transfer operators and, this structure yields a log-normal primordial black-hole mass spectrum, near--scale-invariant ultraviolet behaviour, intrinsic k^3 infrared suppression, subdominant tensor contributions, and a low-Weyl initial geometry. The emergence of observable infrared features is associated with a transition in the Page-time information structure. When the informational roughness exceeds the relevant transition threshold, the primordial spectrum enters a universal k^3 infrared-suppressed regime, with PBH-related signatures arising as a diagnostic response rather than as an assumed cosmological component. A particularly sharp and falsifiable prediction of CBHIRT is the intrinsic k^3 infrared suppression of the primordial curvature spectrum. This suppression arises from Page-time correlation structure and provides a possible informational origin for the observed low- CMB deficit. Although CBHIRT adopts an explicitly non-physical ontology, it is empirically testable and yields quantitative, falsifiable predictions for observable cosmological quantities, including the primordial spectrum, the log-normal PBH mass function, and associated CMB and possible PBH-related gravitational-wave signatures. In this sense, CBHIRT provides a non-singular, low-Weyl, information-defined precursor to the FRW Universe, with predictive primordial signatures that are not freely parameter-tuned but originate from informational structure rather than physical quantum fields, inflationary potentials, or geometric bounce mechanisms. CBHIRT would be falsified by the absence of infrared suppression or by any primordial curvature spectrum inconsistent with the predicted P_ (k) k^3 infrared scaling in the deep infrared.
Darius Seza (Tue,) studied this question.