TY - JOUR
T1 - Generating subgraphs in chordal graphs
AU - Levit, Vadim E.
AU - Tankus, David
N1 - Publisher Copyright:
© 2025 The Author(s)
PY - 2025/6/15
Y1 - 2025/6/15
N2 - A graph G is well-covered if all its maximal independent sets are of the same cardinality. Assume that a weight function w is defined on the vertex set of G. Then G is w-well-covered if all maximal independent sets are of the same weight. For every graph G, the set of weight functions w such that G is w-well-covered is a vector space, denoted WCW(G). Let B be a complete bipartite induced subgraph of G on vertex sets of bipartition BX and BY. Then B is generating if there exists an independent set S such that S∪BX and S∪BY are both maximal independent sets of G. In the restricted case that a generating subgraph B is isomorphic to K1,1, the unique edge in B is called a relating edge. Generating subgraphs play an important role in finding WCW(G). Deciding whether an input graph G is well-covered is co-NP-complete. Hence, finding WCW(G) is co-NP-hard. Deciding whether an edge is relating is NP-complete. Therefore, deciding whether a subgraph is generating is NP-complete as well. A graph is chordal if every induced cycle is a triangle. It is known that finding WCW(G) can be done polynomially in the restricted case that G is chordal. Thus, recognizing well-covered chordal graphs is a polynomial problem. We present a polynomial algorithm for recognizing relating edges and generating subgraphs in chordal graphs.
AB - A graph G is well-covered if all its maximal independent sets are of the same cardinality. Assume that a weight function w is defined on the vertex set of G. Then G is w-well-covered if all maximal independent sets are of the same weight. For every graph G, the set of weight functions w such that G is w-well-covered is a vector space, denoted WCW(G). Let B be a complete bipartite induced subgraph of G on vertex sets of bipartition BX and BY. Then B is generating if there exists an independent set S such that S∪BX and S∪BY are both maximal independent sets of G. In the restricted case that a generating subgraph B is isomorphic to K1,1, the unique edge in B is called a relating edge. Generating subgraphs play an important role in finding WCW(G). Deciding whether an input graph G is well-covered is co-NP-complete. Hence, finding WCW(G) is co-NP-hard. Deciding whether an edge is relating is NP-complete. Therefore, deciding whether a subgraph is generating is NP-complete as well. A graph is chordal if every induced cycle is a triangle. It is known that finding WCW(G) can be done polynomially in the restricted case that G is chordal. Thus, recognizing well-covered chordal graphs is a polynomial problem. We present a polynomial algorithm for recognizing relating edges and generating subgraphs in chordal graphs.
KW - Chordal graph
KW - Generating subgraph
KW - Maximal independent set
KW - Relating edge
KW - Weighted well-covered graph
UR - http://www.scopus.com/inward/record.url?scp=105000074736&partnerID=8YFLogxK
U2 - 10.1016/j.dam.2025.02.042
DO - 10.1016/j.dam.2025.02.042
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AN - SCOPUS:105000074736
SN - 0166-218X
VL - 368
SP - 184
EP - 189
JO - Discrete Applied Mathematics
JF - Discrete Applied Mathematics
ER -