Abstract: We present a systematic quantitative analysis of W, Z bosons, Higgs and Higgs resonance predictions within the 4G model of final unification, centred on a 585 GeV charged weak fermion as a key Higgs‑sector constituent. Using simple geometric‑mean and sum rules applied to single‑ and double‑quark masses, we obtain a structured spectrum of light and heavy Higgs resonances from sub‑GeV up to the TeV scale. In particular, we show that reported excess regions near 95–100 GeV and 630–700 GeV can be naturally interpreted as bottom‑quark and top‑quark light Higgs resonances, respectively, while additional predicted states populate the 600–900 GeV band and around 1 TeV. The same 585 GeV scale also sits naturally between, and conceptually links, the ∼1.17 TeV break in the cosmic‑ray electron–positron spectrum, possible 500–800 GeV Milky Way halo features, and widely discussed supersymmetric Higgsino dark‑matter masses of order 1.1 TeV, suggesting a common weak‑scale hierarchy rather than unrelated energy scales. Taken together, these collider, supersymmetric, and astrophysical indications motivate a dedicated and systematic re‑analysis of LHC data in a framework that integrates the 4G model with the Standard Model. Finally, we show various applications of 585 GeV in particle physics, nuclear physics, atomic physics and astrophysics. While our relations are formulated at a phenomenological level using geometric-mean and charge-based constructions, they are intended as testable organizing principles that can later be embedded in a consistent Lagrangian or effective-field-theory framework.