Self-complementary graph on 4k + 1 vertices

Question

I am self-studying the graph theory book by Bondy and Murty.

On page 31, the author suggests:

Every self-complementary graph on $4k + 1$ vertices has a vertex of degree $2k$.

Here what I have so far:

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Given a self-complementary graph $G = (V, E)$ where $n = 4k + 1, k \geq 1$. We have $$ m = \frac{4k \cdot (4k + 1)}{4} = k \cdot (4k + 1). $$

Furthermore, let $d_G$ denote the sum of degrees of all vertices, then $$ d_G = 2k \cdot (4k + 1) = \frac{n-1}{2} \cdot n $$

So we need to prove that there must exist a vertex with the degree $(n-1)/2$, given $d_G = (n-1)/{2} \cdot n$.

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Why cannot we have the degrees of all vertices different from $(n-1) / 2$, but still achieving the $(n-1) / 2$ average degree?

Answer 1

As the graph is self-complementary, by definition there exists some isomorphism $f$ from the graph to its complement. Consider $f$ as a bijection from the vertex-set of the graph to itself (i.e. a permutation on the vertex-set), and consider the cycle structure of this permutation. As $4k + 1$ is odd, there must be at least one odd cycle. Every vertex in this cycle has the same degree and complementary degree, i.e. $2k$.