In an undirected graph with n
vertices and no edges, what is the maximum number of edges that can be added so that the graph remains unconnected? This is an interview question.
- NC2
- (N-1)C2
- N!
- (N-1)!
In an undirected graph with n
vertices and no edges, what is the maximum number of edges that can be added so that the graph remains unconnected? This is an interview question.
The maximum number of edges in a graph with N vertices is NC2 (link).
Note that, to remain unconnected, one of the vertices should not have any edges. More formally, there has to be a cut (across which there won't be any edges) with one side having only one vertex. Why not more than one vertex? Proof by induction:
The cases for 0, 1 and 2 vertices are trivial.
Consider a graph with 3 vertices. The best cut will be one with 2 vertices on one side and 1 vertex on the other side.
Now assume the best cut is one with N-1 vertices on one side and 1 vertex on the other with N >= 3. Now try to add a vertex. Adding the vertex to the side with one vertex will result in one edge that can be added. Adding the vertex to the other side will result in N-1 possible edges. Clearly N-1 > 1 for N >= 3. Thus it's always better to add the vertex to the side with N-1 vertices.
Now there are two ways to go from here:
Consider the graph without one of the edges. The maximum number of edges of this sub-graph is (N-1)C2
.
Consider the maximum number of edges of the graph as is and subtract the number of edges from one vertex. This gives NC2 - (N-1)
= N(N-1)/2 - 2(N-1)/2
= (N-2)(N-1)/2
= (N-1)C2
.
So the answer is (N-1)C2
, i.e. option 2.
b (n-1)C2
An example of such a graph is a complete graph of n-1 vertices and one isolated vertex.
In this example, the complement graph would have nC2 - (n-1)C2 = n-1 edges. And either given graph or its complement is connected (proof). Hence, if we constucted a graph with more than (n-1)C2 edges, then the complement would have less than n-1 edges and couldn't be connected, so our graph would be.