Proving Degrees of Vertices in Graph G

In summary, the conversation discusses the degrees of vertices in a graph G of order \[2n+1 \geq 5\], which are either n+1 or n+2. The goal is to prove that G must contain at least n+1 vertices of degree n+2 or n+2 vertices of degree n+1. It is suggested to use an argument by contradiction and to show that assuming the opposite leads to a contradiction by counting the number of edges in the graph.
  • #1
Amer
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The degree of every vertex of a graph G of order \[2n+1 \geq 5\] is either n+1 or n+2. Prove that G contains at least n+1 vertices of degree n+2 or at least n+2 vertex
 
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  • #2
Is this question complete? It seems truncated.
 
  • #3
The degree of every vertex of a graph G of order \[2n+1 \geq 5\] is either n+1 or n+2. Prove that G contains at least n+1 vertices of degree n+2 or at least n+2 vertex of degree n+1
 
  • #4
Amer said:
The degree of every vertex of a graph G of order \[2n+1 \geq 5\] is either n+1 or n+2. Prove that G contains at least n+1 vertices of degree n+2 or at least n+2 vertices of degree n+1
Try using an argument by contradiction. Suppose that there are $x$ vertices of degree $n+1$, and $y$ vertices of degree $n+2$, and suppose that the result is false. Then $x\leqslant n+1$ and $y\leqslant n$. But $x+y=2n+1$. It follows that we must have $x=n+1$ and $y=n.$ By counting the number of edges in the graph, show that this leads to a contradiction.
 
  • #5
I would like to begin by stating that the given statement is a well-known and established fact in the field of graph theory. The degree of a vertex in a graph G refers to the number of edges incident to that vertex. Therefore, the given statement is essentially stating that in a graph G with an odd number of vertices, the degree of each vertex can only be either n+1 or n+2.

To prove this statement, let's consider a graph G with an odd number of vertices, 2n+1. We know that the sum of degrees of all vertices in a graph is equal to twice the number of edges (Handshaking Lemma). In other words, the sum of degrees of all vertices in G is equal to 2|E|.

Now, let's assume that the degree of each vertex in G is either n+1 or n+2. This means that the sum of degrees of all vertices in G can be written as follows:

(n+1) + (n+2) + (n+1) + (n+2) + ... + (n+1) + (n+2)

= (n+1)n/2 + (n+2)n/2

= (n^2 + 3n)/2

Since we know that the sum of degrees of all vertices in G is equal to 2|E|, we can equate the two expressions and solve for |E| as follows:

2|E| = (n^2 + 3n)/2

|E| = (n^2 + 3n)/4

Since n is an integer, n^2 + 3n is always divisible by 4. Therefore, |E| is also an integer. This means that the number of edges in G must be an even number.

However, we know that in any graph, the number of edges must be an integer. Therefore, the number of edges in G must be either an even number or an odd number. But we have just shown that the number of edges in G must be an even number. This means that the number of edges in G cannot be an odd number.

But if the number of edges in G is not an odd number, then it must be an even number. And if the number of edges in G is an even number, then it must be divisible by 2. This means that the number
 

FAQ: Proving Degrees of Vertices in Graph G

1. What does "proving degrees of vertices" mean in a graph?

"Proving degrees of vertices" refers to determining the number of edges connected to each vertex in a given graph. In other words, it is the measure of the number of connections or neighbors that a particular vertex has in the graph.

2. Why is proving degrees of vertices important in graph theory?

Proving degrees of vertices is important in graph theory because it provides crucial information about the structure and connectivity of a graph. It helps in understanding the relationships between different vertices and how they are interconnected.

3. How do you prove the degrees of vertices in a graph?

To prove the degrees of vertices in a graph, you can use the handshaking lemma, which states that the sum of degrees of all vertices in a graph is equal to twice the number of edges. You can also use visual methods, such as drawing the graph and counting the number of edges connected to each vertex.

4. Can a vertex have a degree of 0 in a graph?

Yes, a vertex can have a degree of 0 in a graph. This means that the vertex is not connected to any other vertex in the graph. In other words, it has no neighbors or edges connected to it.

5. How does the degree distribution of a graph affect its properties?

The degree distribution of a graph can affect its properties in various ways. For example, a graph with a high degree distribution may have a higher level of connectivity and complexity compared to a graph with a low degree distribution. It can also impact the efficiency of algorithms used to analyze the graph and identify important vertices.

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