WMCP and WMISP admit O*(2^k) algorithms on graphs with G-edge distance k whenever the problems are polynomial-time solvable on the base hereditary class G.
Structural Bounds and Forbidden Induced Subgraphs for Edge-Add Graph Classes
1 Pith paper cite this work. Polarity classification is still indexing.
abstract
A class $\mathcal{G}$ of graphs is hereditary if it is closed under taking induced subgraphs. We investigate the edge-add class, $\mathcal{G}^{\mathrm{add}}$, consisting of graphs that can be made members of $\mathcal{G}$ by adding at most one edge. While it is known that the operations of vertex deletion and edge deletion preserve the finiteness of forbidden induced subgraphs for classes with finite exclusions, the behavior of edge addition on classes with infinite exclusions remains largely unexplored. We characterize the edge-add class of chordal graphs by their forbidden induced subgraphs and extend the result to a general finiteness theorem: for any fixed $p\ge0$, the set of forbidden induced subgraphs for $p$-edge-add chordal graphs that are not cycles is finite. In contrast, we show that this phenomenon does not extend to perfect graphs. Furthermore, we provide explicit structural bounds proving that edge addition preserves finiteness for base classes with finitely many exclusions. We conclude by providing the complete structural characterizations and explicit minimal obstruction lists for the edge-add classes of split and threshold graphs, and generalize these results to $(p,q)$-edge split graphs.
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cs.DS 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Weighted Clique and Independent Set in Edge-Distant Hereditary Graphs
WMCP and WMISP admit O*(2^k) algorithms on graphs with G-edge distance k whenever the problems are polynomial-time solvable on the base hereditary class G.