English

Reconfiguration on nowhere dense graph classes

Discrete Mathematics 2018-09-12 v2

Abstract

Let Q\mathcal{Q} be a vertex subset problem on graphs. In a reconfiguration variant of Q\mathcal{Q} we are given a graph GG and two feasible solutions Ss,StV(G)S_s, S_t\subseteq V(G) of Q\mathcal{Q} with Ss=St=k|S_s|=|S_t|=k. The problem is to determine whether there exists a sequence S1,,SnS_1,\ldots,S_n of feasible solutions, where S1=SsS_1=S_s, Sn=StS_n=S_t, Sik±1|S_i|\leq k\pm 1, and each Si+1S_{i+1} results from SiS_i, 1i<n1\leq i<n, by the addition or removal of a single vertex. We prove that for every nowhere dense class of graphs and for every integer r1r\geq 1 there exists a polynomial prp_r such that the reconfiguration variants of the distance-rr independent set problem and the distance-rr dominating set problem admit kernels of size pr(k)p_r(k). If kk is equal to the size of a minimum distance-rr dominating set, then for any fixed ϵ>0\epsilon>0 we even obtain a kernel of almost linear size O(k1+ϵ)\mathcal{O}(k^{1+\epsilon}). We then prove that if a class C\mathcal{C} is somewhere dense and closed under taking subgraphs, then for some value of r1r\geq 1 the reconfiguration variants of the above problems on C\mathcal{C} are W[1]\mathsf{W}[1]-hard (and in particular we cannot expect the existence of kernelization algorithms). Hence our results show that the limit of tractability for the reconfiguration variants of the distance-rr independent set problem and distance-rr dominating set problem on subgraph closed graph classes lies exactly on the boundary between nowhere denseness and somewhere denseness.

Keywords

Cite

@article{arxiv.1707.06775,
  title  = {Reconfiguration on nowhere dense graph classes},
  author = {Sebastian Siebertz},
  journal= {arXiv preprint arXiv:1707.06775},
  year   = {2018}
}
R2 v1 2026-06-22T20:53:38.404Z