Section 5.1[edit | edit source]

Remember the definitions:
Definition 5.3.1 Let $A$ and $B$ be non-empty sets, let $R$ be a relation from $A$ to $B$ , and let $x\in A$ . The relation class of $x$ with respect to $R$ , denoted $R[x]$ , is the set defined by $R[x]=\{y\in B|xRy\}$ .
Definition 2.2.1 Let $a$ and $b$ be integers. The number $a$ divides the number $b$ if there is some integer $q$ such that $aq=b$ . If $a$ divides $b$ , we write $a|b$ , and we say that $a$ is a factor of $b$ , and that $b$ is divisible by $a$ .

5.1.1[edit | edit source]

Let $aSb\Leftrightarrow a=|b|$ , for all $a,b\in \mathbb {Z}$ . Then
$S[3]=\{b\in \mathbb {Z} :3Sb\}$ , but by the definition of the relation $S$ is $S[3]=\{b\in \mathbb {Z} :3=|b|\}$ and the only elements that satisfy this property are $3$ and $-3$ , since $3=|3|=|-3|$ and therefore $S[3]=\{-3,3\}$ . Analogously, we have to:
$S[-3]=\{b\in \mathbb {Z} :-3Sb\}=\{b\in \mathbb {Z} :-3=|b|\}=\emptyset$ .
$S[6]=\{b\in \mathbb {Z} :6Sb\}=\{b\in \mathbb {Z} :6=|b|\}=\{-6,6\}$ .
Let $aDb\Leftrightarrow a|b$ , for all $a,b\in \mathbb {Z}$ . Then
$D[3]=\{b\in \mathbb {Z} :3Db\}=\{b\in \mathbb {Z} :\exists k\in \mathbb {Z} {\text{ and }}b=3k\}=\{...,-6,-3,-1,0,1,3,6,...\}$ .
$D[-3]=\{b\in \mathbb {Z} :-3Db\}=\{b\in \mathbb {Z} :\exists k\in \mathbb {Z} {\text{ and }}b=-3k\}=\{...,-6,-3,-1,0,1,3,6,...\}$ .
$D[6]=\{b\in \mathbb {Z} :6Db\}=\{b\in \mathbb {Z} :\exists k\in \mathbb {Z} {\text{ and }}b=6k\}=\{...,-12,-6,0,6,12,...\}$ .
Let $aTb\Leftrightarrow b|a$ , for all $a,b\in \mathbb {Z}$ . Then
$T[3]=\{b\in \mathbb {Z} :3Tb\}=\{b\in \mathbb {Z} :b|3\}=\{b\in \mathbb {Z} :\exists k\in \mathbb {Z} {\text{ and }}3=bk\}=\{-3,-1,1,3\}$ .
$T[-3]=\{b\in \mathbb {Z} :-3Tb\}=\{b\in \mathbb {Z} :b|-3\}=\{b\in \mathbb {Z} :\exists k\in \mathbb {Z} {\text{ and }}-3=bk\}=\{-3,-1,1,3\}$ .
$T[6]=\{b\in \mathbb {Z} :6Tb\}=\{b\in \mathbb {Z} :b|6\}=\{b\in \mathbb {Z} :\exists k\in \mathbb {Z} {\text{ and }}6=bk\}=\{-6,-3,2,-1,1,2,3,6\}$ .
Let $aQb\Leftrightarrow a+b=7$ , for all $a,b\in \mathbb {Z}$ . Then
$Q[3]=\{b\in \mathbb {Z} :3Qb\}=\{b\in \mathbb {Z} :3+b=7\}=\{4\}$ .
$Q[-3]=\{b\in \mathbb {Z} :-3Qb\}=\{b\in \mathbb {Z} :-3+b=7\}=\{10\}$ .
$Q[6]=\{b\in \mathbb {Z} :6Qb\}=\{b\in \mathbb {Z} :6+b=7\}=\{1\}$ .

5.1.2[edit | edit source]

Let $S$ be the relation defined by $(x,y)S(z,w)\Leftrightarrow y=3w{\text{ for all }}(x,y),(z,w)\in \mathbb {R} ^{2}$ .
$S[(0,0)]=\{(z,w)\in \mathbb {R} ^{2}:(0,0)S(z,w)\}=\{(z,0)\}$ . Because $y=3w\Rightarrow 0=3w$ , and therefore $w=0$ . The geometric description of the relation class are: the $x$ -axis.
$S[(3,4)]=\{(z,w)\in \mathbb {R} ^{2}:(3,4)S(z,w)\}=\{(z,{\dfrac {4}{3}})\}$ . Because $y=3w\Rightarrow 4=3w$ , and therefore $w={\dfrac {4}{3}}$ . The geometric description of the relation class are: the the line whose equation is $y={\dfrac {4}{3}}$ .
Let $T$ be the relation defined by $(x,y)T(z,w)\Leftrightarrow x^{2}+3y^{2}=7z^{2}+w^{2}{\text{, for all }}(x,y),(z,w)\in \mathbb {R} ^{2}$ .
$T[(0,0)]=\{(z,w)\in \mathbb {R} ^{2}:(0,0)T(z,w)\}=(0,0).Because0^{2}+3\cdot 0^{2}=7z^{2}+w^{2}\Rightarrow Z=0andw=o$ .
$T[(3,4)]=\{(z,w)\in \mathbb {R} ^{2}:(3,4)T(z,w)\}=\{(z,{\sqrt {57-7z^{2}}})\}$ . Because $3^{2}+3\cdot 4^{2}=7z^{2}+w^{2}\Rightarrow w={\sqrt {57-7z^{2}}}$ . The geometric description of the relation class are the graph of $y={\sqrt {57-7z^{2}}}$ .
Let $Z$ be the relation defined by $(x,y)T(z,w)\Leftrightarrow x=z\vee y=w{\text{, for all }}(x,y),(z,w)\in \mathbb {R} ^{2}$ .
$Z[(0,0)]=\{(z,w)\in \mathbb {R} ^{2}:(0,0)Z(z,w)\}=\{(0,w)\vee (z,0)\}$ .
$Z[(3,4)]=\{(z,w)\in \mathbb {R} ^{2}:(3,4)Z(z,w)\}=\{(3,w)\vee (z,4)\}$ .