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From Skiena's book, This is not HW, and merely my preparation for an interview.

Given this question,

A matching of an undirected graph G = (V, E) is a set of edges no two of which have a vertex in common. A perfect matching is a matching in which all vertices are matched.

(a) Construct a graph G with 2n vertices and n^2 edges such that G has an an expo- nential number of perfect matchings.

(b) Construct a graph G with 2n vertices and n^2 edges such that G has exactly one unique perfect matching.

I just have no idea how to begin. For a, I chose n = 3, so I now know I have 6 vertices and 9 edges, and tried connecting them, but I didn't know if it was perfect matching.

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No undirected graph can have n^2 edges; is n^2 what you mean when you write n2? A clique has (n^2-n)/2 edges. This must be talking about multigraphs then. Also, in what variable is the number of perfect matchings in (a) supposed to be exponential? –  G. Bach Apr 20 '13 at 17:28
    
@G.Bach I mean N^2, it says to construct a graph with 2n edges, and n^2 edges –  user2302617 Apr 20 '13 at 17:32
    
It must be talking about non-simple graphs then, and probably multigraphs, because even a complete directed graph with self loops has only n^2 edges. –  G. Bach Apr 20 '13 at 17:34
    
@G.Bach it doesn't specify, what I've posted is what the question is, and I couldn't solve it. –  user2302617 Apr 20 '13 at 17:39
    
@G.Bach: There are twice as many vertices as you think. –  tmyklebu Apr 20 '13 at 17:51

2 Answers 2

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  1. For a): take a complete bipartite graph over 2n vertices with both partitions having n vertices each. These graphs have n! perfect matchings, which is more than 2^n for n > 2.
  2. For b): We build something similar to a complete bipartite graph over (n,n) vertices. Call the partitions A=(1,2,3,...,n) and B=(n+1,n+2,n+3,...2n).

    Make A a clique.

    For every vertex n+i in B, add an edge (n+i,j) for every vertex j in A with j<=i. For example, vertex n+1 only is incident to the edge (n+1,1); the vertex n+2 is incident to (n+2, 1) and (n+2,2); the vertex n+3 is incident to (n+3,1) (n+3,2) (n+3,3).

    This forces the unique perfect matching to be {e in E | e = (n+i,i) for some i in [1;n]} (try to prove this to practice induction).

    Since A is a clique over n vertices, it has n^2/2 - n/2 edges. The edges running between A and B are a total of sum from 1 to n which is n^2/2 + n/2, so together we get
    n^2/2 - n/2 + n^2/2 + n/2 = n^2 edges.

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Probably this graph will help you for (a):

V={1,2,a,b}

E={(1,a),(1,b),(2,a),(2,b)}

2*2 vertices

2^2 edges

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