This preprint presents a compact synthesis of the Gauged Constant Vacuum-Mode (GCV) route to the cosmological constant problem (CCP). The underlying GCV record has become modular enough that a reader would otherwise need to reconstruct the full claim by moving across separate papers on radiative stability, residual Lambdaₑff, UV anchoring, survey-facing interfaces, value selection, and sign selection. The purpose of the present paper is therefore programmatic rather than derivational: it states the three CCP pillars addressed by GCV, explains the four-step route by which they were reached, and clarifies the appropriate completion criterion for a flux-discretuum framework. The first pillar is radiative stability. On the GR-exact branch of GCV, the strictly spacetime-constant vacuum mode is gauge/flux-controlled and does not reappear as a freely running local cosmological-constant coupling. The local Einstein equations retain GR form with a flux-fixed integration constant Lambdaₑff, while local excitations gravitate normally. The second pillar is observed-value localization. Starting from the radiatively stable GR-exact branch, the numerical-selection, closeout, and UV budget-partition modules compress the residual-value problem from order-unity to near-unity and then to a narrow UV-selected operational window. In the current synthesis, that stage yields a viable UV-pass interval dₚass = 178, 206, aligned with independent geometry statistics near the population median dₚroxy ≈ 200. The third pillar is positive-Lambda realization. Once the magnitude stage is fixed near the observed residual scale, late-time cosmological viability introduces a physical asymmetry between the two signs: Lambda 0 universes do not. The surviving near-zero residuals are therefore biased toward the positive branch. Within the stated GR-exact branch and module assumptions, the synthesis argues that GCV resolves the three classical CCP pillars at programme level up to a narrow UV-selected discretuum rather than a unique continuous endpoint: radiative stability is secured first, the allowed magnitude is localized near the observed scale, and the positive branch is selected by late-time viability. The paper does not claim a unique UV completion or a purely ultraviolet theorem for the sign. Its role is to provide a compact entry point to the GCV programme and a clear map connecting the companion records. Project homepage: https: //johansson. digital Project overview hub: https: //github. com/gcv-framework/gcv-vacuum-energy
Germund Johansson (Fri,) studied this question.