English

Minimum Cost Homomorphisms to Proper Interval Graphs and Bigraphs

Discrete Mathematics 2007-05-23 v2 Artificial Intelligence

Abstract

For graphs GG and HH, a mapping f:V(G)\domV(H)f: V(G)\dom V(H) is a homomorphism of GG to HH if uvE(G)uv\in E(G) implies f(u)f(v)E(H).f(u)f(v)\in E(H). If, moreover, each vertex uV(G)u \in V(G) is associated with costs ci(u),iV(H)c_i(u), i \in V(H), then the cost of the homomorphism ff is uV(G)cf(u)(u)\sum_{u\in V(G)}c_{f(u)}(u). For each fixed graph HH, we have the {\em minimum cost homomorphism problem}, written as MinHOM(H)H). The problem is to decide, for an input graph GG with costs ci(u),c_i(u), uV(G),iV(H)u \in V(G), i\in V(H), whether there exists a homomorphism of GG to HH and, if one exists, to find one of minimum cost. Minimum cost homomorphism problems encompass (or are related to) many well studied optimization problems. We describe a dichotomy of the minimum cost homomorphism problems for graphs HH, with loops allowed. When each connected component of HH is either a reflexive proper interval graph or an irreflexive proper interval bigraph, the problem MinHOM(H)H) is polynomial time solvable. In all other cases the problem MinHOM(H)H) is NP-hard. This solves an open problem from an earlier paper. Along the way, we prove a new characterization of the class of proper interval bigraphs.

Keywords

Cite

@article{arxiv.cs/0602038,
  title  = {Minimum Cost Homomorphisms to Proper Interval Graphs and Bigraphs},
  author = {G. Gutin and P. Hell and A. Rafiey and A. Yeo},
  journal= {arXiv preprint arXiv:cs/0602038},
  year   = {2007}
}