🚧 Setup for 4.9
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@ -8823,3 +8823,143 @@ Omitted.
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_multiplicative identity_.)
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_multiplicative identity_.)
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Omitted.
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Omitted.
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---
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**Exercise Set 4.9**
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Page 265
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In 1 and 2 find the degree of each vertex and the total degree of the graph.
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Check that the number of edges equals one-half of the total degree.
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1. See page 265.
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2. See page 265.
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3. A graph has vertices of degrees 0, 2, 2, 3, and 9. How many edges does the
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graph have?
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4. A graph has vertices of degrees 1, 1, 4, 4, and 6. How many edges does the
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graph have?
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In each of 5-13 either draw a graph with the specified properties or explain why
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no such graph exists.
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5. Graph with five vertices of degrees 1, 2, 3, 3, and 5.
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6. Graph of four vertices of degrees 1, 2, 3, and 3.
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7. Graph with four vertices of degrees 1, 1, 1, and 4.
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8. Graph with four vertices of degrees 1, 2, 3, and 4.
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9. Simple graph with four vertices of degrees 1, 2, 3, and 4.
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10. Simple graph with five vertices of degrees 2, 3, 3, 3, and 5.
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11. Simple graph with five vertices of degrees 1, 1, 1, 2, and 3.
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12. Simple graph with six edges and all vertices of degree 3.
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13. Simple graph with nine edges and all vertices of degree 3.
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14. At a party attended by a group of people, two people knew one other person
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before the party, and five people knew two other people before the party.
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The rest of the people knew three other people before the party. A total of
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15 pairs of people knew each other before the party.
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a. How many people attending the party knew three other people before the party?
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b. How many people attended the party?
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15. A small social network contains three people who are network friends with
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six other people in the network, one person who is network friend with five
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other people in the network, and five people who are network friends with
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four other people in the network. The rest are network friends with three
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other people in the network. The network contains 41 pairs of network
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friends.
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a. How many people are network friends with three other people in the network?
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b. How many people are in the network?
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16.
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a. In a group of 15 people, is it possible for each person to have exactly 3
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friends? Justify your answer. (Assume that friendship is a symmetric
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relationship: If $x$ is a friend of $y$, then $y$ is a friend of $x$.)
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b. In a group of 4 people, is it possible for each person to have exactly 3
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friends? Justify your answer.
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17. In a group of 25 people, is it possible for each to shake hands with exactly
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3 other people? Justify your answer.
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18. Is there a simple graph, each of whose vertices has even degree? Justify
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your answer.
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19. Suppose that $G$ is a graph with $v$ vertices and $e$ edges and that the
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degree of each vertex is at least $d_{\text{min}}$ and at most
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$d_{\text{max}}$. Show that
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$$ \frac{1}{2}d_{\text{min}} \cdot v \leq e \leq \frac{1}{2}d_{\text{max}} \cdot v $$
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20.
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a. Draw $K_6$, a complete graph on six vertices.
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b. Use the result of Example 4.9.9 to show that the number of edges of a simple
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graph with $n$ vertices is less than or equal to $\dfrac{n(n - 1)}{2}$.
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21.
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a. In a simple graph, must every vertex have degree that is less than the number
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of vertices in the graph? Why?
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b. Can there be a simple graph that has four vertices all of different degrees?
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Why?
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c. For any integer $n \geq 5$, can there be a simple graph that has $n$ vertices
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all of different degrees? Why?
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22. In a group of two or more people, must there always be at least two people
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who are acquainted with the same number of people within the group? Why?
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23. Recall that $K_{m, n}$ denotes a complete bipartite graph on $(m, n)$
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vertices.
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a. Draw $K_{4, 2}$.
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b. Draw $K_{1, 3}$.
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c. Draw $K_{3, 4}$.
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d. How many vertices of $K_{m, n}$ have degree $m$? degree $n$?
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e. What is the total degree of $K_{m, n}$?
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f. Find a formula in terms of $m$ and $n$ for the number of edges of $K_{m, n}$.
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Justify your answer.
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24. A (general) **bipartite graph** $G$ is a simple graph whose vertex set can
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be partitioned into two disjoint nonempty subsets $V_1$ and $V_2$ such that
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vertices in $V_1$ may be connected to vertices in $V_2$, but no vertices in
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$V_1$ and no vertices in $V_2$ are connected to other vertices in $V_2$. For
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example, the bipartite graph $G$ illustrated in (i) can be redrawn as shown
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in (ii). From the drawing in (ii), you can see that $G$ is bipartite with
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mutually disjoint vertex sets $V_w = \{v_1, v_3, v_5\}$ and
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$V_2 = \{v_2, v_4, v_6\}$.
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(i) See Page 266
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(ii) See Page 266
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Find which of the following graphs are bipartite. Redraw the bipartite graphs so
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that their bipartite nature is evident.
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See Page 266.
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25. Suppose $r$ and $s$ are any positive integers. Does there exist a graph $G$
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with the property that $G$ has vertices of degrees $r$ and $s$ and no other
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degrees? Explain.
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@ -1110,3 +1110,135 @@ does not divide $(2 \cdot 3 \cdot 5 \cdot 7 \cdot 11 \dots p) + 1$, which equals
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$N$. Hence $N$ is divisible by $q$ and $N$ is not divisible by $q$, and we have
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$N$. Hence $N$ is divisible by $q$ and $N$ is not divisible by $q$, and we have
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reached a contradiction. _[Therefore, the supposition is false and the theorem
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reached a contradiction. _[Therefore, the supposition is false and the theorem
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is true.]_
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is true.]_
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---
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Page 258
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**Definition**
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The total degree of a graph is the sum of the degrees of all the vertices of the
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graph.
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---
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Page 259
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**Theorem 4.9.1 The Handshake Theorem**
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If $G$ is any graph, then the sum of the degrees of all the vertices of $G$
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equals twice the number of edges of $G$. Specifically, if the vertices of $G$
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are $v_1, v^2, \dots v_n$, where $n$ is a nonnegative integer, then
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$$ \text{the total degree of } G = \text{deg}(v_1) + \text{deg}(v_2) + \dots + \text{deg}(v_n) $$
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$$ = 2 \cdot (\text{the number of edges of } G) $$
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**Proof:**
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Let $G$ be a particular but arbitrarily chosen graph, and suppose that $G$ has
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$n$ vertices $v_1, v_2, \dots v_n$ and $m$ edges, where $n$ is a positive
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integer and $m$ is a nonnegative integer. We claim that each edge of $G$
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contributes $2$ to the total degree of $G$. For suppose $e$ is an arbitrarily
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chosen edge with endpoints $v_i$ and $v_j$. This edge contributes $1$ to the
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degree of $v_i$ and $1$ to the degree of $v_j$. As shown below, this is true
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even if $i = j$, because an edge that is a loop is counted twice in computing
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the degree of the vertex on which it is incident.
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(see Page 259)
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Therefore, $e$ contributes $2$ to the total degree of $G$. Since $e$ was
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arbitrarily chosen, this shows that _each_ edge of $G$ contributes $2$ to the
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total degree of $G$. Thus
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$$ \text{the total degree of } G = 2 \cdot (\text{the number of edges of } G) $$
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---
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Page 259
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**Corollary 4.9.2**
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The total degree of a graph is even.
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**Proof:** By Theorem 4.9.1 the total degree of $G$ equals $2$ times the number
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of edges of $G$, which is an integer, and so the total degree of $G$ is even.
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---
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Page 260
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**Proposition 4.9.3**
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In any graph there is an even number of vertices of odd degree.
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**Proof:** Suppose $G$ is any graph, and suppose $G$ has $n$ vertices of odd
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degree and $m$ vertices of even degree, where $n$ is a positive integer and $m$
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is a nonnegative integer. _[We must show that $n$ is even.]_ Let $E$ be the sum
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of the degrees of all the vertices of even degree, $O$ the sum of the degrees of
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all the vertices of odd degree, and $T$ the total degree of $G$. If
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$u_1, u_2, \dots, u_m$ are the vertices of even degree and
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$v_1, v_2, \dots, v_n$ are the vertices of odd degree, then
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$$ E = \text{deg}(u_1) + \text{deg}(u_2) + \dots + \text{deg}(u_m), $$
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$$ O = \text{deg}(v_1) + \text{deg}(v_2) + \dots + \text{deg}(v_m), \text{ and} $$
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$$ T = \text{deg}(u_1) + \dots + \text{deg}(u_m) + \text{deg}(v_1) + \dots + \text{deg}(v_n) = E + 0 $$
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Now $T$, the total degree of $G$, is an even integer by Corollary 4.9.2. Also
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$E$ is even since either $E$ is zero, which is even, or $E$ is a sum of even
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numbers. Now since
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$$ T = E + O $$
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then
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$$ O = T - E $$
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Hence $O$ is a difference of two even integers, and so $O$ is even.
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By assumption, $\text{deg}(v_i)$ is odd for every integer $i = 1, 2, \dots, n$.
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Thus $O$, an even integer, is a sum of the $n$ odd integers
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$\text{deg}(v_1), \text{deg}(v_2), \dots, \text{deg}(v_n)$. But if a sum of $n$
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odd integers is even, then $n$ is even. Therefore, $n$ is even _[as was to be
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shown]._
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---
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Page 262
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**Definition and Notation**
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A **simple graph** is a graph that does not have any loops or parallel edges. In
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a simple graph, an edge with endpoints $v$ and $w$ is denoted $\{v, w\}$.
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---
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Page 263
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**Definition**
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Let $n$ be a positive integer. A **complete graph on $n$ vertices**, denoted
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$K_n$, is a simple graph with $n$ vertices and exactly one edge connecting each
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pair of distinct vertices.
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---
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Page 264
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**Definition**
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Let $m$ and $n$ be positive integers. A **complete bipartite graph on $(m, n)$
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vertices**, denoted $K_{m, n}$, is a simple graph whose vertices are divided
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into two distinct subsets, $V$ with $m$ vertices and $W$ with $n$ vertices, in
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such a way that
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1. every vertex of $K_{m, n}$ belongs to one of $V$ or $W$, but no vertex
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belongs to both $V$ and $W$;
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2. there is exactly one edge from each vertex of $V$ to each vertex of $W$;
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3. there is no edge from any one vertex of $V$ to any other vertex of $V$;
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4. there is no edge from any one vertex of $W$ to any other vertex of $W$.
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@ -249,3 +249,26 @@ that integer is even; have a common factor greater than 1.
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greater than ______.
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greater than ______.
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$N = (2 \cdot 3 \cdot 5 \cdot 7 \cdot 11 \cdot \dots \cdot p) + 1$; $p$
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$N = (2 \cdot 3 \cdot 5 \cdot 7 \cdot 11 \cdot \dots \cdot p) + 1$; $p$
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---
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**Test Yourself**
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Page 265
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1. The total degree of a graph is defined as ______.
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2. The handshake theorem says that the total degree of a graph is ______.
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3. In any graph the number of vertices of odd degree is ______.
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4. A simple graph is ______.
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5. A complete graph on $n$ vertices is a ______.
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6. A complete bipartite graph on $(m, n)$ vertices is a simple graph whose
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vertices can be divided into two distinct, non-overlapping sets, say $V$ with
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$m$ vertices and $W$ with $m$ vertices, in such a way that (1) there is
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______ from each vertex of $V$ to each vertex of $W$, (2) there is ______
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from any one vertex of $V$ to any other of $V$, and (3) there is ______ from
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any one vertex of $W$ to any other vertex of $W$.
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