🚧 Setup for 4.3
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@ -1857,3 +1857,241 @@ Thus there exists an nonnegative integer $n$ such that $2^{2n} + 1$ is not
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prime, and therefore the given statement is false.
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Q.E.D.
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---
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**Exercise Set 4.3**
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Page 210
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The numbers in 1-7 are all rational. Write each number as a ratio of two
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integers.
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1. $-\dfrac{35}{6}$
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2. $4.6037$
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3. $\dfrac{4}{5} + \dfrac{2}{9}$
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4. $0.37373737\dots$
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5. $0.56565656\dots$
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6. $320.5492492492\dots$
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7. $52.4672167216721\dots$
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8. The zero product property, says that if a product of two real numbers is $0$,
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then one of the numbers must be $0$.
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a. Write this property formally using quantifiers and variables.
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b. Write the contrapositive of your answer to part (a).
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c. Write an informal version (without quantifier symbols or variables) for your
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part to part (b).
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9. Assume that $a$ and $b$ are both integers and that $a \neq 0$ and $b \neq 0$.
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Explain why $\dfrac{(b - a)}{(ab^2)}$ must be a rational number.
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10. Assume that $m$ and $n$ are both integers and that $n \neq 0$. Explain why
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$\dfrac{(5m - 12n)}{(4n)}$ must be a rational number.
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11. Prove that every integer is a rational number.
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12. Let $S$ be the statement "The square of any rational number is rational." A
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formal version of $S$ is "For every rational number $r$, $r^2$ is rational."
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Fill in the blanks in the proof for $S$.
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**Proof:**
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Suppose that $r$ is __ (a) __. By definition of rational, $r = \dfrac{a}{b}$ for
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some __ (b) __ with $b \neq 0$. By substitution,
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$$ r^2 = \text{\_\_ (c) \_\_} = \frac{a^2}{b^2} $$
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Since $a$ and $b$ are both integers, so are the products $a^2$ and __ (d) __.
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Also $b^2 \neq 0$ by the __ (e) __. Hence $r^2$ is a ratio of two integers with
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a non-zero denominator,n and so __ (f) __ by definition of rational.
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13. Consider the following statement: The negative of any rational number is
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rational.
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a. Write the statement formally using a quantifier and a variable.
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b. Determine whether the statement is true or false and justify your answer.
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14. Consider the statement: The cube of any rational number is a rational
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number.
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a. Write the statement formally using a quantifier and a variable.
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b. Determine whether the statement is true or false and justify your answer.
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Determine which of the statements in 15-19 are true and which are false. Prove
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each true statement directly from the definitions, and give a counterexample for
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each false statement. For a statement that is false, determine whether a small
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change would make it true. If so, make the change and prove the new statement.
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Follow the directions for writing proofs on page 173.
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15. The product of any two rational numbers is a rational number.
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16. The quotient of any two rational numbers is a rational number.
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17. The difference of any two rational numbers is a rational number.
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18. If $r$ and $s$ are any two rational numbers, then $\dfrac{r + s}{2}$ is
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rational.
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19. For all real numbers $a$ and $b$, if $a < b$ then
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$a < \dfrac{a + b}{2} < b$.
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(You may use the properties of inequalities in T17-T27 of Appendix A.)
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20. Use the results of exercises 18 and 19 to prove that given any two rational
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numbers $r$ and $s$ with $r < s$, there is another rational number between
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$r$ and $s$. An important consequence is that there are infinitely many
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rational numbers in between any two distinct rational numbers. See Section
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7.4.
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Use the properties of even and odd integers that are listed in Example 4.3.3 to
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do exercises 21-23. Indicate which properties you use to justify your reasoning.
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21. True or false? If $m$ is any even integer and $n$ is any odd integer, then
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$m^2 + 3n$ is odd. Explain.
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22. True or false? If $a$ is any odd integer, then $a^2 + a$ is even. Explain.
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23. True or false? If $k$ is any even integer and $m$ is any odd integer, then
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$(k + 2)^2 - (m - 1)^2$ is even. Explain.
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Derive the statements in 24-26 as corollaries of Theorems 4.3.1, 4.3.2, and the
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results of exercises 12, 13, 14, 15, and 17.
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24. For any rational numbers $r$ and $s$, $2r + 3s$ is rational.
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25. If $r$ is any rational number, then $3r^2 - 2r + 4$ is rational.
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26. For any rational number $s$, $5s^3 + 8s^2 - 7$ is rational.
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27. It is a fact that if $n$ is any nonnegative integer, then
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$$ 1 + \frac{1}{2} + \frac{1}{2^2} + \frac{1}{2^3} + \dots + \frac{1}{2^n} = \frac{1 - \left(\dfrac{1}{2^{n + 1}}\right)}{1 - \left(\dfrac{1}{2}\right)} $$
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(A more general form of this statement is proved in Section 5.2.) Is the
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right-hand side of this equation rational? If so, express it as a ratio of two
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integers.
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28. Suppose $a$, $b$, $c$, and $d$ are integers and $a \neq c$. Suppose also
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that $x$ is a real number that satisfies the equation
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$$ \frac{ax + b}{cs + d} = 1 $$
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Must $x$ be rational? If so, express $x$ as a ratio of two integers.
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29. Suppose $a$, $b$, and $c$ are integers and $x$, $y$, and $z$ are nonzero
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real numbers that satisfy the following equations:
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$$ \frac{xy}{x + y} = a \quad \text{ and } \quad \frac{xz}{x + z} = b \quad \text{ and } \quad \frac{yz}{y + z} = c $$
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Is $x$ rational? If so, express it as ratio of two integers.
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30. Prove that if one solution for a quadratic equation of the form
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$x^2 + bx + c = 0$ is rational (where $b$ and $c$ are rational), then the
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other solution is also rational. (Use the fact that if the solutions of the
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equation are $r$ and $s$, then $x^2 + bx + c = (x - r)(x - s)$.)
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31. Prove that if a real number $c$ satisfies a polynomial equation of the form
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$$ r_3x^3 + r_2x^2 + r_1x + r_0 = 0 $$
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where $r_0$, $r_1$, $r_2$, and $r_3$ are rational numbers, then $c$ satisfies an
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equation of the form
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$$ n_3x^3 + n_2x^2 + n_1x + n_0 = 0 $$
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where $n_0$, $n_1$, $n_2$, and $n_3$ are integers.
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**Definition:** A number $c$ is called a **root** of a polynomial $p(x)$ if, and
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only if, $p(c) = 0$.
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32. Prove that for every real number $c$, if $c$ is a root of a polynomial with
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rational coefficients, then $c$ is a root of a polynomial with integer
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coefficients.
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Use the properties of even and odd integers that are listed in Example 4.3.3 to
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do exercises 33 and 34.
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33. When expressions of the form $(x - r)(x - s)$ are multiplied out, a
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quadratic polynomial is obtained. For instance,
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$(x - 2)(x - (-7)) = (x - 2)(x + 7) = x^2 + 5x - 14$.
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a. What can be said about the coefficients of the polynomial obtained by
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multiplying out $(x - r)(x - s)$ when both $r$ and $s$ are odd integers? When
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both $r$ and $s$ are even integers? When one of $r$ and $s$ is even and the
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other odd?
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b. It follows from part (a) that $x^2 - 1253x + 255$ cannot be written as a
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product of two polynomials with integer coefficients. Explain why this is so.
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34. Observe that
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$$ (x - r)(x -s)(x - t) = x^3 - (r + s + t)x^2 + (rs + rs + st)x - rst $$
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a. Derive a result for cubic polynomials similar to the result in part (a) of
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exercise 33 for quadratic polynomials.
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b. Can $x^3 + 7x^2 - 8x - 27$ be written as a product of three polynomials with
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integer coefficients? Explain.
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In 35-39 find the mistakes in the "proofs" that the sum of any two rational
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numbers is a rational number.
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35.
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**"Proof:** Any two rational numbers produce a rational number when added
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together. So if $r$ and $s$ are particular but arbitrarily chosen rational
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numbers, then $r + s$ is rational."
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36.
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**"Proof:** Let rational numbers $r = \dfrac{1}{4}$ and $s = \dfrac{1}{2}$ be
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given. Then $r + s = \dfrac{1}{4} + \dfrac{1}{2} = \dfrac{3}{4}$, which is a
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rational number. This is what was to be shown."
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37.
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**"Proof:** Suppose $r$ and $s$ are rational numbers. By definition of rational,
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$r = \dfrac{a}{b}$ for some integers $a$ and $b$ with $b \neq 0$, and
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$s = \dfrac{a}{b}$ for some integers $a$ and $b$ with $b \neq 0$. Then
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$$ r + s = \frac{a}{b} + \frac{a}{b} = \frac{2a}{b} $$
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Let $p = 2a$. Then $p$ is an integer since it is a product of integers. Hence
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$r + s = \dfrac{p}{b}$, where $p$ and $b$ are integers and $b \neq 0$. Thus
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$r + s$ is a rational number by definition of rational. This is what was to be
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shown."
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38.
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**"Proof:** Suppose $r$ and $s$ are rational numbers. Then $r = \dfrac{a}{b}$
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and $s = \dfrac{c}{d}$ for some integers $a$, $b$, $c$, and $d$ with $b \neq 0$
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and $d \neq 0$ (by definition of rational.) Then
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$$ r + s = \frac{a}{b} + \frac{c}{d} $$
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But this is a sum of two fractions, which is a fraction. So $r - s$ is a
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rational number since a rational number is a fraction."
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39.
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**"Proof:** Suppose $r$ and $s$ are rational numbers. If $r + s$ is rational,
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then by definition of rational $r + s = \dfrac{a}{b}$ for some integers $a$ and
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$b$ with $b \neq 0$. Also since $r$ and $s$ are rational, $r = \dfrac{i}{j}$ and
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$s = \dfrac{m}{n}$ for some integers $i$, $j$, $m$, and $n$ with $j \neq 0$ and
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$n \neq 0$. It follows that
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$$ r + s = \frac{i}{j} + \frac{m}{n} = \frac{a}{b} $$
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which is a quotient of two integers with a nonzero denominator. Hence it is a
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rational number. This is what is to be shown.
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@ -111,3 +111,67 @@ Page 196
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Personal Note: The entirety of 4.2 is extremely helpful in breaking down in
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exactly how to write proofs (for beginners). I'd advise revisiting this entire
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section frequently.
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---
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Page 206
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**Definition**
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A real number $r$ is **rational** if, and only if, it can be expressed as a
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quotient of two integers with a nonzero denominator. A real number that is not
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rational is **irrational**. More formally, if $r$ is a real number, then
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$$ r \text{ is rational } \Leftrightarrow \exists \text{ integers } a \text{ and } b \text{ such that } r = \frac{a}{b} \text{ and } b \neq 0 $$
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---
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Page 207
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**Zero Product Property**
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If neither of two real numbers is zero, then their product is also not zero.
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---
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Page 208
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**Theorem 4.3.1**
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Every integer is a rational number.
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---
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Page 209
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**Theorem 4.3.2**
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The sum of any two rational numbers is rational.
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**Proof:**
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Suppose $r$ and $s$ are any rational numbers. _[We must show that $r + s$ is
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rational.]_ Then, by definition of rational, $r = \dfrac{a}{b}$ and
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$s = \dfrac{c}{d}$ for some integers $a$, $b$, $c$, and $d$ with $b \neq 0$ and
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$d \neq 0$. Thus
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$$ r + s = \frac{a}{b} + \frac{c}{d} \quad \text{ by substitution} $$
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$$ \quad = \frac{ad + bc}{bd} \quad \text{ by basic algebra} $$
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Let $p = ad + bc$ and $q = bd$. Then $p$ and $q$ are integers because products
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and sums of integers are integers and because $a$, $b$, $c$, and $d$ are
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integers. Also $q \neq 0$ by the zero product property. Thus
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$$ r + s = \frac{p}{q} \text{ where } p \text{ and } q \text{ are integers and } q \neq 0 $$
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Therefore, $r + s$ is rational by the definition of a rational number _[as was
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to be shown]_.
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---
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Page 210
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**Corollary 4.2.3**
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The double of a rational number is rational.
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@ -82,3 +82,16 @@ arguing from examples; using the same letter to mean two different things;
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jumping to a conclusion; assuming what is to be proved; confusion between what
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is known and what is still to be shown; use of _any_ when the correct word is
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_some_; misuse of the word _if_
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---
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**Test Yourself**
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Page 210
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1. To show that a real number is rational, we must show that we can write it as
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______.
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2. An irrational number is a ______ that is ______.
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3. Zero is a rational number because ______.
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