Existence as Distinguishability: Quantum Mechanics from Finite Graded Equality

Abstract

We derive finite-dimensional quantum mechanics from a single ontological principle, that existence is constituted by distinguishability, together with two structural commitments: finite capacity N (parametric input) and self-referential consistency (SRC, a closure schema with two equivalent forms, operational and information-theoretic). SRC unpacks into eight derived structural conditions; structural unambiguity (S5) completes the hierarchy, uniquely selecting the Born rule as the geometric/probabilistic closure. The graded distinguishability kernel K(x,y) ∈ [0,1] realises both axioms, with a state constituted by its K-profile against all others. For each N ≥ 3, the unique distinguishability space is (C PN-1, K) with K(,φ) = 1 - ||φ|2, from which complex coefficients, the Born rule pk = |ck|2, unitary dynamics, and tensor-product composition all follow. Indeterminism is forced by capacity overflow; alternatives (e.g. Bohmian mechanics) are classified rather than refuted. Standard QM is the N ∞ limit; finite N is the only free parameter. The algebraic spine is machine-checked in Lean 4 modulo five imported classical theorems and the existence direction of Stone's theorem; the Appendix states the verification scope.

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