English

Carath\'eodory Number in Cycle Convexity

Combinatorics 2026-04-23 v1

Abstract

Let GG be a graph and SV(G)S \subseteq V(G). In the cycle convexity, we say that SS is \textit{cycle convex} if for any uV(G)Su\in V(G)\setminus S, the induced subgraph of S{u}S\cup\{u\} contains no cycle that includes uu. The \textit{cycle convex hull} of SS, denoted by \hullc(S)\hullc (S), is the smallest cycle convex set containing SS. A set SV(G)S \subseteq V(G) is said to be \textit{Carath\'eodory independent} if there exists a vertex u\hullc(S)u \in \hullc(S) such that uaS\hullc(S{a})u \notin\displaystyle \bigcup_{a \in S} \hullc (S \setminus \{a\}) , and the Carath\'eodory number \car(G)\car(G) is the maximum size of such a set. In this paper, we prove that given a graph GG and kNk \in \mathbb{N}, deciding whether \car(G)k\car(G) \geq k is \NP-complete, even when GG is bipartite. On the other hand, we derive exact values and constant upper bounds for several graph classes, leading to polynomial-time algorithms. Some of them include forests, cycles, complete graphs, complete multipartite, split, and P4P_4-sparse graphs. In addition, we present a characterization of nn-vertex graphs GG with extremal values near to nn, including \car(G)=n1\car(G) = n-1 and \car(G)=n2\car(G) = n-2. Furthermore, we investigate the behavior of the Carath\'eodory number under graph products such as the strong, lexicographic, and Cartesian products.

Keywords

Cite

@article{arxiv.2604.20097,
  title  = {Carath\'eodory Number in Cycle Convexity},
  author = {Revathy S. Nair and Bijo S. Anand and Ullas Chandran S. V. and Julliano R. Nascimento},
  journal= {arXiv preprint arXiv:2604.20097},
  year   = {2026}
}
R2 v1 2026-07-01T12:29:34.660Z