Add to ORKGIn this paper, an algorithm for determining 3-colorability, i.e. the decision problem (YES/NO), in planar graphs is presented. The algorithm, although not exact (it could produce false positives) has two very important features: (i) it has polynomial complexity and (ii) for every “NO ” answer, a “short ” proof is generated, which is of much interest since 3-colorability is a NP-complete problem and thus its complementary problem is in Co-NP. Hence the algorithm is exact when it determines that a given planar graph is not 3-colorable since this is verifiable via an automatic generation of short formal proofs (also human-readable)
AbstractIn this paper, we mainly prove that planar graphs without 4-, 7- and 9-cycles are 3-colorabl...
In this paper we prove that every planar graph without 4, 5 and 8-cycles is 3-colorable
Let G be a planar triangle-free graph and let C be a cycle in G of length at most 8. We characterize...
AbstractGraph coloring for 3-colorable graphs receives very much attention by many researchers in th...
Although deciding whether the vertices of a planar graph can be colored with three colors is NP-hard...
AbstractIt is well known that the problem of graph k-colourability, for any k≥3, is NP-complete but ...
AbstractWe prove that the Satisfiability (resp. planar Satisfiability) problem is parsimoniously P-t...
We present a polynomial time approximation algorithm to colour a 3-colourable graph G with 3f(n) col...
AbstractA graph G is k-choosable if for every assignment of a set S(v) of k colors to every vertex v...
It is one of the open problems, whether or not the algorithm for a 3-coloring graph is in polynomial...
AbstractIt is shown that two sorts of problems belong to the NP-complete class. First, it is proven ...
Many practical problems in almost all scientific and technological disciplines have been classified ...
Electronic version of an article published as International Journal of Computational Geometry & Appl...
Many practical problems in almost all scientific and technological disciplines have been classified ...
AbstractWe show that the question “Is a graph 3-colorable?” remains NP-complete when restricted to t...
AbstractIn this paper, we mainly prove that planar graphs without 4-, 7- and 9-cycles are 3-colorabl...
In this paper we prove that every planar graph without 4, 5 and 8-cycles is 3-colorable
Let G be a planar triangle-free graph and let C be a cycle in G of length at most 8. We characterize...
AbstractGraph coloring for 3-colorable graphs receives very much attention by many researchers in th...
Although deciding whether the vertices of a planar graph can be colored with three colors is NP-hard...
AbstractIt is well known that the problem of graph k-colourability, for any k≥3, is NP-complete but ...
AbstractWe prove that the Satisfiability (resp. planar Satisfiability) problem is parsimoniously P-t...
We present a polynomial time approximation algorithm to colour a 3-colourable graph G with 3f(n) col...
AbstractA graph G is k-choosable if for every assignment of a set S(v) of k colors to every vertex v...
It is one of the open problems, whether or not the algorithm for a 3-coloring graph is in polynomial...
AbstractIt is shown that two sorts of problems belong to the NP-complete class. First, it is proven ...
Many practical problems in almost all scientific and technological disciplines have been classified ...
Electronic version of an article published as International Journal of Computational Geometry & Appl...
Many practical problems in almost all scientific and technological disciplines have been classified ...
AbstractWe show that the question “Is a graph 3-colorable?” remains NP-complete when restricted to t...
AbstractIn this paper, we mainly prove that planar graphs without 4-, 7- and 9-cycles are 3-colorabl...
In this paper we prove that every planar graph without 4, 5 and 8-cycles is 3-colorable
Let G be a planar triangle-free graph and let C be a cycle in G of length at most 8. We characterize...