From Finite-Node Conifold Geometry to BPS Structures I: Algebraic State Data

Abstract

Let π:X be a one-parameter degeneration whose central fiber X0 is a complex threefold with finitely many ordinary double points =\p1,…,pr\⊂ X0. Associated with this degeneration is the corrected finite-node perverse extension, together with its mixed-Hodge-module refinement and a finite-node schober datum whose perverse-sheaf shadow is identified with the corrected perverse sheaf P. The purpose of the present paper is to extract from these finite-node geometric, extension-theoretic, mixed-Hodge, and categorical inputs the intrinsic algebraic state data carried by the degeneration. More precisely, we isolate the finite localized quotient Q:=k=1r ik*\pk\, the nodewise coupling space E:=1(X0;)(Q,ICX0), its canonical nodewise decomposition E_k=1r ek, and the coefficient vector c=(c1,…,cr)∈r defined by [ P]perv=Σk=1r ck ek. We then prove that these state variables are compatible with both the mixed-Hodge-module lift and the schober realization of P, so that the same finite-node architecture appears simultaneously in perverse, mixed-Hodge, and categorical form. The resulting package (V,E,c) is the intrinsic algebraic state data attached to the finite-node conifold degeneration. It provides the first algebraic layer in the passage from finite-node geometry to later incidence, quiver, stability, BPS-spectral, and wall-crossing structures.