This paper establishes that the standard number systems ℕ, ℤ, ℚ, ℝ, and ℂ are not pre-existing mathematical objects but structures uniquely selected by the operational constraints of the rank-3 minimal operational closure C⁽³⁾_Πd as formalised in Operatiology. The selection order is constrained by the axioms: Axiom 1 contains a geometric-persistence clause expressed using the distance function d, which is defined only in Axiom 2. Therefore ℝ, the number system selected by Axiom 2, must be established before ℂ, the number system selected by the orbital structure of Axiom 1. Axiom 2 selects ℝ as the unique totally ordered, complete Archimedean field. Axioms 1 and 4 identify ℕ, ℤ, and ℚ as the minimal discrete substructures of ℝ required for distinguishability, reversibility, and minimal description. Axiom 1 also generates bilateral inaccessibility between non-commutative orbit pairs, producing a canonical ℤ/2ℤ symmetry. By Galois theory, the unique minimal realisation of this symmetry over ℝ is ℂ, making ℂ the number system structurally demanded by non-commutativity. Working Axiom 3 is not invoked; all results follow from A1, A2, and A4. Numbers and the algebra M₃ (ℂ) are co-derived from the same axiomatic source via the chain C⁽³⁾_Πd → ℳ₁ → M₃ (ℂ), showing that mathematics functions as the projective layer generated by, and subordinate to, the executive structure of Operatiology. Numbers, in this framework, are not discovered or invented; they are what operational closure structurally requires. This version supersedes the prior Cognitional Mechanics formulation (DOI: 10. 5281/zenodo. 20108822). The transition from Cognitional Mechanics to Operatiology replaces the earlier grounding in "intelligence" as a technical term with the structurally deeper foundation of C⁽³⁾_Πd, and reframes the mathematical projection hierarchy in terms of the five-layer distance ordering established in the companion paper on mathematics as the unique top-down projection of operational structure.
T.O. (Thu,) studied this question.