🚧 Setup for 3.2
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@ -671,3 +671,284 @@ d. $a < b \text{ and } c < d \Rightarrow ac < bd$
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This is false. Say $a = -1$, $b = 2$, $c = -8$ and $d = 3$. This would make
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$-1 < 2$ and $-8 < 3$, which is true, but then $(-1)(-8) < (2)(3)$ would be
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$8 < 6$, which is false.
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---
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**Exercise Set 3.2**
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Page 152
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1. Which of the following is a negation for "All discrete mathematics students
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are athletic"? More than one answer may be correct.
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a. There is a discrete mathematics student who is nonathletic.
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b. All discrete mathematics students are nonathletic.
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c. There is an athletic person who is not a discrete mathematics student.
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d. No discrete mathematics students are athletic.
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e. Some discrete mathematics students are nonathletic.
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f. No athletic people are discrete mathematics students.
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2. Which of the following is a negation for "All dogs are loyal"? More than one
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answer may be correct.
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a. All dogs are disloyal.
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b. No dogs are loyal.
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c. Some dogs are disloyal.
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d. Some dogs are loyal.
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e. There is a disloyal animal that is not a dog.
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f. There is a dog that is disloyal.
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g. No animals that are not dogs are loyal.
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h. Some animals that are not dogs are loyal.
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3. Write the formal negation for each of the following statements.
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a. $\forall$ string $s$, $s$ has at least one character.
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b. $\forall$ computer $c$, $c$ has a CPU.
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c. $\exists$ a movie $m$ such that $m$ is over 6 hours long.
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d. $\exists$ a band $b$ such that $b$ has won at least 10 Grammy awards.
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4. Write an informal negation for each of the following statements. Be careful
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to avoid negations that are ambiguous.
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a. All dogs are friendly.
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b. All graphs are connected.
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c. Some suspicions were substantiated.
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d. Some estimates are accurate.
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5. Write a negation for each of the following statements.
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a. Every valid argument has a true conclusion.
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b. All real numbers are positive, negative, or zero.
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Write a negation for each statement in 6 and 7.
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6.
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a. Sets $A$ and $B$ do not have any points in common.
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b. Towns $P$ and $Q$ are not connected by any road on the map.
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7.
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a. This vertex is not connected to any other vertex in the graph.
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b. This number is not related to any even number.
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8. Consider the statement "There are no simple solutions to life's problems."
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Write an informal negation for the statement, and then write the statement
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formally using quantifiers and variables.
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Write a negation for each statement in 9 and 10.
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9. $\forall$ real number $x$, if $x > 3$ then $x^2 > 9$.
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10. $\forall$ computer program $P$, if $P$ compiles without error messages, then
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$P$ is correct.
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In each of 11-14 determine whether the proposed negation is correct. If it is
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not, write a correct negation.
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11.
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_Statement:_ The sum of any two irrational numbers is irrational.
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_Proposed negation:_ The sum of any two irrational numbers is rational.
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12.
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_Statement:_ The product of any irrational number and any rational number is
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irrational.
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_Proposed negation:_ The product of any irrational number and any rational
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number is rational.
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13.
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_Statement:_ For every integer $n$, if $n^2$ is even then $n$ is even.
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_Proposed negation:_ For every integer $n$, if $n^2$ is even then $n$ is not
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even.
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14.
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_Statement:_ For all real numbers $x_1$ and $x_2$, if $x_1^2 = x_2^2$ then
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$x_1 = x_2$.
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_Proposed negation:_ For all real numbers $x_1$ and $x_2$, if $x_1^2 = x_2^2$
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then $x_1 \neq x_2$.
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15. Let $D = \{-48, -14, -8, 0, 1, 3, 16, 23, 26, 32, 36\}$. Determine which of
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the following statements are true and which are false. Provide
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counterexamples for the statements that are false.
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a. $\forall x \in D, \text{ if } x \text{ is odd then } x > 0$.
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b.
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$\forall x \in D, \text{ if } x \text{ is less than } 0 \text{ then } x \text{ is even}$.
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c. $\forall x \in D, \text{ if } x \text{ is even then } x \leq 0$.
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d.
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$\forall x \in D, \text{ if the ones digit of } x \text{ is } 2, \text{ then the tens digit is } 3 \text{ or } 4$.
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e.
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$\forall x \in D, \text{ if the ones digit of } x \text{ is } 6, \text{ then the tens digit is } 1 \text{ or } 2$.
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In 16-23, write a negation for each statement.
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16. $\forall$ real number $x$, if $x^2 \geq 1$ then $x > 0$.
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17. $\forall$ integer $d$, if $\dfrac{6}{d}$ is an integer then $d = 3$.
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18. $\forall x \in \mathbb{R}$, if $x(x + 1) > 0$ then $x > 0$ or $x < -1$.
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19. $\forall x \in \mathbb{Z}$, if $n$ is prime then $n$ is odd or $n = 2$.
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20. $\forall$ integers $a$, $b$, and $c$, if $a - b$ is even and $b - c$ is
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even, then $a - c$ is even.
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21. $\forall$ integer $n$, if $n$ is divisible by $6$, then $n$ is divisible by
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$2$ and $n$ is divisible by $3$.
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22. If the square of an integer is odd, then the integer is odd.
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23. If a function is differentiable then it is continuous.
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24. Rewrite the statements in each pair in if-then form and indicate the logical
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relationship between them.
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a.
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All the children in Tom's family are female.
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All the females in Tom's family are children.
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b.
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All the integers that are greater than 5 and end in 1, 3, 7, or 9 are prime.
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All the integers that are greater than 5 and are prime end in 1, 3, 7, or 9.
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25. Each of the following statements is true. In each case write the converse
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statement, and give a counterexample showing that the converse is false.
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a. If $n$ is any prime number that is greater than $2$, then $n + 1$ is even.
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b. If $m$ is an odd integer, then $2m$ is even.
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c. If two circles intersect in exactly two points, then they do not have a
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common center.
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In 26-33, for each statement in the referenced exercise write the
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contrapositive, converse, and inverse. Indicate as best as you can which of
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these statements are true and which are false. Give a counterexample for each
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that is false.
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26. Exercise 16
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27. Exercise 17
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28. Exercise 18
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29. Exercise 19
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30. Exercise 20
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31. Exercise 21
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32. Exercise 22
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33. Exercise 23
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34. Write the contrapositive for each of the following statements.
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a. If $n$ is prime, then $n$ is not divisible by any prime number from $2$
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through $\sqrt{n}$. (Assume that $n$ is a fixed integer.)
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b. If $A$ and $B$ do not have any elements in common, then they are disjoint.
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(Assume that $A$ and $B$ are fixed sets.)
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35. Give an example to show that a universal conditional statement is not
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logically equivalent to its inverse.
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36. If $P(x)$ is a predicate and the domain of $x$ is the set of all real
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numbers, let $R$ be "$\forall x \in \mathbb{Z}, P(x)$" let $S$ be
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"$\forall x \in \mathbb{Q}, P(x)$", and let $T$ be
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"$\forall x \in \mathbb{R}, P(x)$."
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a. Find a definition for $P(x)$ (but do not use "$x \in \mathbb{Z}$") so that
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$R$ is true and both $S$ and $T$ are false.
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b. Find a definition for $P(x)$ (but do not use "$x \in \mathbb{Q}$") so that
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both $R$ and $S$ are true and $T$ is false.
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37. Consider the following sequence of digits: 0204. A person claims that all
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the 1's in the sequence are to the left of all the 0's in the sequence. Is
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this true? Justify your answer. (_Hint:_ Write the claim formally and write
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a formal negation of it. Is the negation true or false?)
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38. True or false? All occurrences of the letter _u_ in _Discrete Mathematics_
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are lowercase. Justify your answer.
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Rewrite each statement of 39-44 in if-then form.
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39. Earning a grade of C- in this course is a sufficient condition for it to
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count toward graduation.
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40. Being divisible by 8 is a sufficient condition for being divisible by 4.
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41. Being on time each day is a necessary condition for keeping this job.
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42. Passing a comprehensive exam is a necessary condition for obtaining a
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master's degree.
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43. A number is prime only if it is greater than 1.
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44. A polygon is square only if it has four sides.
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Use the fact that the negation of a $\forall$ statement is a $\exists$ statement
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and that the negation of an if-then statement is an _and_ statement to rewrite
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each of the statements 45-48 without using the word _necessary_ or _sufficient_.
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45. Being divisible by 8 is not a necessary condition for being divisible by 4.
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46. Having a large income is not a necessary condition for a person to be happy.
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47. Having a large income is not a sufficient condition for a person to be
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happy.
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48. Being a polynomial is not a sufficient condition for a function to have a
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real root.
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49. The computer scientists Richard Conway and David Gries once wrote:
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> The absence of error messages during translation of a computer program is only
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> a necessary and not a sufficient condition for reasonable [program]
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> correctness.
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Rewrite this statement without using the words _necessary_ or _sufficient_.
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50. A frequent-flyer club brochure states, "You may select among carriers only
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if they offer the same lowest fare." Assuming that "only if" has its formal,
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logical meaning, does this statement guarantee that if two carriers offer
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the same lowest fare, the customer will be free to choose between them?
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Explain.
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@ -58,3 +58,84 @@ Let $P(x)$ and $Q(x)$ be predicates and suppose the domain of $x$ is $D$.
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- The notation $P(x) \Leftrightarrow Q(x)$ means that $P(x)$ and $Q(x)$ have
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identical truth sets, or, equivalently,
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$\forall x, P(x) \leftrightarrow Q(x)$.
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---
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Page 145
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**Theorem 3.2.1 Negation of a Universal Statement**
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The negation of a statement of the form
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$$ \forall \text{ in } D, Q(x) $$
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is logically equivalent to a statement of the form
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$$ \exists \text{ in } D \text{ such that } \neg Q(x) $$
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Symbolically,
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$$ \neg(\forall x \in D, Q(x)) \equiv \exists x \in D \text{ such that } \neg Q(x) $$
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---
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Page 146
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**Theorem 3.2.2 Negation of an Existential Statement**
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The negation of a statement of the form
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$$ \exists \text{ in } D \text{ such that } Q(x) $$
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is logically equivalent to a statement of the form
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$$ \forall x \text{ in } D, \neg Q(x) $$
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Symbolically,
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$$ \neg(\exists x \in D \text{ such that } Q(x)) \equiv \forall x \in D, \neg Q(x) $$
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---
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Page 148
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**Negation of a Universal Conditional Statement**
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$$ \neg(\forall x, \text{ if } P(x) \text{ then } Q(x)) \equiv \exists x \text{ such that } P(x) \text{ and } \neg Q(x) $$
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$$ \neg(\forall x, P(x) \to Q(x)) \equiv \exists x, (P(x) \wedge \neg Q(x)) $$
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---
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Page 150
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**Definition**
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Consider a statement of the form
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$\forall x \in D, \text{ if } P(x) \text{ then } Q(x)$.
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1. Its **contrapositive** is the statement
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$\forall x \in D, \text{ if } \neg Q(x) \text{ then } \neg P(x)$.
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2. Its **converse** is the statement
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$\forall x \in D, \text{ if } Q(x) \text{ then } P(x)$.
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3. Its **inverse** is the statement
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$\forall x \in D, \text{ if } \neg P(x) \text{ then } \neg Q(x)$.
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---
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Page 151
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**Definition**
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- "$\forall x, r(x)$ is a **sufficient condition** for $s(x)$" means
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"$\forall x, \text{ if } r(x) \text{ then } s(x)$."
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- "$\forall x, r(x)$ is a **necessary condition** for $s(x)$" means
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"$\forall x, \text{ if } \neg r(x) \text{ then } \neg s(x)$" or, equivalently,
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"$\forall x, \text{ if } s(x) \text{ then } r(x)$."
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- "$\forall x, r(x)$ **only if** $s(x)$" means
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"$\forall x, \text{ if } \neg s(x) \text{ then } \neg r(x)$" or, equivalently,
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"$\forall x, \text{ if } r(x) \text{ then } s(x)$."
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@ -25,3 +25,41 @@ true; every $x$ in $D$.
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only if, $Q(x)$ is _______ for _______.
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true; at least one $x$ in $D$.
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---
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**Test Yourself**
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Page 152
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1. A negation for "All $R$ have property $S$" is "There is _______ $R$ that
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_______."
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exists at least one; does not have property $S$.
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2. A negation for "Some $R$ have property $S$" is "_______."
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"No $R$ have property $S$."
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3. A negation for "For every $x$, if $x$ has property $P$ then $x$ has property
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$Q$" is "_______."
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"There exists at least one $x$ such that $x$ has property $P$ and $x$ does not
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have property $Q$."
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4. The converse of "For every $x$, if $x$ has property $P$ then $x$ has property
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$Q$" is "_______."
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"For every $x$, if $x$ has property $Q$ then $x$ has property $P$."
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5. The contrapositive of "For every $x$, if $x$ has property $P$ then $x$ has
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property $Q$" is "_______."
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"For every $x$, if $x$ does not have property $Q$, then $x$ does not have
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property $P$."
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6. The inverse of "For every $x$, if $x$ has property $P$ then $x$ has property
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$Q$" is "_______."
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"For every $x$, if $x$ does not have property $P$, then $x$ does not have
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property $Q$."
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