Annihilation, Independence, and Residue: Sharp Matching Bounds for the Annihilation Gap and a TxGraffiti Application
Abstract
Let G be a finite simple graph. The annihilation number a(G) is an efficiently computable upper bound on the independence number α(G). We develop a sharp matching-number theory for the gap a(G)-α(G). The strongest general theorem is the exact closed form \[a(G)-α(G)≤ 2μ(G)+1- 6 μ(G) (μ(G)≥ 1), \] and the bound is attained for every prescribed matching number. We also prove sharp matching-dependent bounds for forests, bipartite graphs, and König-Egerváry graphs, with equality constructions, equality certificates, and equality criteria. Finally, we treat a TxGraffiti output as a machine-conjecture case study. Using annihilating decompositions together with the classical Havel-Hakimi residue inequality res(G)≤ α(G), we give an independent proof of the TxGraffiti annihilation-residue inequality \[ α(G)≥ a(G)+res(G)Δ(G) \] for every connected graph G of order at least three, show that both hypotheses are necessary, and compare this proof with a recent Caro-Wei approach. We also refine the Caro-Wei annihilation estimate by an explicit nonnegative slack term, identify its equality cases in degree-sequence form, and combine the refinement with our exact matching-number bound to obtain a combined computable bracket for the independence number and a Gupta-residue bound for the annihilation gap.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.