A homomorphism from a graph G to a graph H is locally bijective, surjective, or injective if its restriction to the neighborhood of every vertex of G is bijective, surjective, or injective, respectively. We prove that the problems of testing whether a given graph G allows a homomorphism to a given graph H that is locally bijective, surjective, or injective, respectively, are NP-complete, even when G has pathwidth at most 5, 4 or 2, respectively, or when both G and H have maximum degree 3. We complement these hardness results by showing that the three problems are polynomial-time solvable if G has bounded treewidth and in addition G or H has bounded maximum degree
A graph homomorphism is an edge preserving vertex mapping between two graphs. Locally constrained ho...
A homomorphism from a graph GG to a graph HH is a vertex mapping f:VG→VHf:VG→VH such that f(u)f(u) a...
A homomorphism from a graph G to a graph H is a vertex mapping f from the vertex set of G to the ver...
A homomorphism from a graph G to a graph H is locally bijective, surjective, or injective if its res...
A homomorphism from a graph G to a graph H is locally bijective, surjective, or injective if its res...
Abstract. A homomorphism from a graph G to a graph H is locally bijective, surjective, or injective ...
A homomorphism from a graph G to a graph H is locally bijective, injective, or surjective if its res...
A homomorphism from a graph g to a graph h is locally bijective, surjective, or injective if its res...
A homomorphism φ from a guest graph G to a host graph H is locally bijective, injective or surjecti...
The Surjective Homomorphism problem is to test whether a given graph G called the guest graph allows...
A homomorphism ϕ from a guest graph G to a host graph H is locally bijective, injective or surjectiv...
AbstractWe explore the connection between locally constrained graph homomorphisms and degree matrice...
The universal cover T G of a connected graph G is the unique (possibly infinite) tree covering G, i....
Abstract. The Surjective Homomorphism problem is to test whether a given graph G called the guest gr...
A locally surjective homomorphism from a graph G to a graph H is an edge-preserving mapping from V(G...
A graph homomorphism is an edge preserving vertex mapping between two graphs. Locally constrained ho...
A homomorphism from a graph GG to a graph HH is a vertex mapping f:VG→VHf:VG→VH such that f(u)f(u) a...
A homomorphism from a graph G to a graph H is a vertex mapping f from the vertex set of G to the ver...
A homomorphism from a graph G to a graph H is locally bijective, surjective, or injective if its res...
A homomorphism from a graph G to a graph H is locally bijective, surjective, or injective if its res...
Abstract. A homomorphism from a graph G to a graph H is locally bijective, surjective, or injective ...
A homomorphism from a graph G to a graph H is locally bijective, injective, or surjective if its res...
A homomorphism from a graph g to a graph h is locally bijective, surjective, or injective if its res...
A homomorphism φ from a guest graph G to a host graph H is locally bijective, injective or surjecti...
The Surjective Homomorphism problem is to test whether a given graph G called the guest graph allows...
A homomorphism ϕ from a guest graph G to a host graph H is locally bijective, injective or surjectiv...
AbstractWe explore the connection between locally constrained graph homomorphisms and degree matrice...
The universal cover T G of a connected graph G is the unique (possibly infinite) tree covering G, i....
Abstract. The Surjective Homomorphism problem is to test whether a given graph G called the guest gr...
A locally surjective homomorphism from a graph G to a graph H is an edge-preserving mapping from V(G...
A graph homomorphism is an edge preserving vertex mapping between two graphs. Locally constrained ho...
A homomorphism from a graph GG to a graph HH is a vertex mapping f:VG→VHf:VG→VH such that f(u)f(u) a...
A homomorphism from a graph G to a graph H is a vertex mapping f from the vertex set of G to the ver...