Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

# Graph theory - chromatic index

I have to make a program which will say if graph is d colorable or not - basically i have to check if chromatic index is d or d+1, where d is max degree of all vertices (vizing's theorem). I know this problem is NP-complete and basically it has to be bruteforced. I had an idea but don't know if it is correct -

1) find vertex with deg(v) = d and color all edges incident with v with d distnict colors.

2) for all edges incident with vertices which are adjacent to v, apply some color from set of d colors

3) repeat 2) for "discovered" edges

If all edges are colored with d colors, chromatic index is d and i have one coloring of graph G.

If some edge can't be colored with color from set of d colors, color him with d+1-st color and color remaining edges with colors from set of d+1 colors - here is the question - using this scheme, if i proclaim that chromatic index to be d+1, is there a chance that with some other coloring chromatic index would be d? (for every edge that is going to be colored I'm choosing one color which can be used)..

Also, which graph representation would be best for this problem? In input file graph is written in adjacency matrix. i know it can be solved with recursion, but I don't have an idea how. I'm stuck with some too complicated ideas :S (some hint or pseudocode would be appreciated).

### Edit:

Just came across my mind, I think it should be ok (pure bruteforce). I didnt try to implement this yet. Please comment if you see something wrong. Just to say again - algorithm should check whether graph is edge colorable with d or d+1 colors where d is max degree of all vertices in given simple graph, and to find one coloring...

``````colorEdge(edge, color, extra) {
if (edge colored) return;  //if already colored, return
if (can be colored in color) color it; //if color can be applied, apply it
else {
//else, 'd+1'-st color neded, so color it with that color, continue finding
//coloring with d+1 colors
extra = true;
color it in color extra;
}

//recursivly try to color adjacent edges with available colors
for each color c' from set of d colors {
for each edge k adjacent to current {
colorE(k, c', extra)
}
}
}

//main
bool extra = false;
for each color b from set of d colors {
colorEdge(some starting edge, b, extra)
if (!extra) break;
}
``````
-
I think this is more appropriate for cstheory.stackexchange.com – GWW May 25 '11 at 20:19
Have you looked into Boost Graph Coloring (boost.org/doc/libs/1_46_1/libs/graph/doc/graph_coloring.html)? – yasouser May 25 '11 at 20:22
thanks for reply - as i see, boost graph coloring is for vertex coloring only, but i need edge coloring (probably it could be modified (eg translating my graf in line graph and than applying given algorithm).. also, this is some kind of homework, but, im not asking someone to do it, just need an idea/little help :) – Goran F May 25 '11 at 20:34
@gww - it's already posted there but I'm happy to leave open here because it staddles both sites. – Kev May 25 '11 at 20:52
Are you after an exact or an approximate algorithm? This all depends on the number of vertices and and edges on the graph G = (V, E). Exact algorithms are only feasible for very small problems. – GordyD May 25 '11 at 22:15

Generate constraints for each edge, assign different colours to all edges of the vertex with the most edges and then process each edges from the most constrained edge.

``````for each edge e1
for each edge e2
if (e1 and e2 have a common vertex)

vertex v = vertex with most edges
if (v has more edges than colours we have available) STOP
assign each edge of v a different colour

Sort edges by number of constraints
Remove all edges connected to v (thus assigned a colour)

process(edge) :=
while (haven't tried all colours within the constraints)
edge.colour = next untried colour within the constraints
process(next most constrained edge)

process(most constrained edge)
``````

It may be a good idea to defined the most constrained edge as the one with the most surrounding edges that have already been assigned colours, but this could cause quite a bit of overhead.

-

transforming your graph to use the vertex coloring algorithm is quite straightforward: for each edge (x,y) in the original graph create a vertex xy in the transformed graph, and for each vertex x in the original graph create edges between all vertices in the transformed graph containing x in their name.

Cheers

-