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We're learning about domains and setbuilder notation in school at the moment, and I want to make sure what I did was right.

My thought process: \begin{align*} -\frac12|4x - 8| - 1 &< -1 \\ -\frac12|4x - 8| &< 0 \\ |4x - 8| &> 0 \end{align*} $x =$ all real numbers.

{real numbers} :

<||||||||||[0]|||||||||>

{x| x is any real number}

{whole numbers}

... <----[-2]---[-1]---[0]---[1]---[2]---> ...

{x|...-2,-1,0,1,2...}

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    There's not much organization, so it's hard to tell what you're asking. It's not true that every real number $x$ satisfies |4x - 8| > 0, and it seems like you might be saying that, but I was hoping someone else would write an answer (I'm surprised that this hasn't happened yet). I may yet do so after finishing this section of my book.2011-12-19

2 Answers 2

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First let's consider how absolute-value is defined:

$ |a| = \begin{cases} a, & \text{if } a \geq 0, \\ -a, &\text{if } a \lt 0. \end{cases} $

Therefore,

$4x-8 > +0\phantom{.}$

$4x-8 < -0.$

Now, solve for $x$ to get the answer:

$x > 2\phantom{.}$

or $x < 2.$

Note: This is same as $ x \neq 2.$

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    Thanks a lot, you just made me realize something important. I was treating the greater-than sign as a greater-than-or-equal-to sign.2011-12-19
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You get $|4x - 8| > 0$, which I agree with; now you want to find all $x$ satisfying this inequality. It's true that for any number $y$ we have $|y| \geq 0$, but equality can hold: $|y| = 0$ if and only if $y = 0$. Use this fact to find the single value $a$ of $x$ for which $|4x - 8| = 0$. In set-builder notation, I would write this as \[ \{x \mid x \neq a\} \qquad \text{or, more carefully,} \qquad \{x \in \mathbb R \mid x \neq a\}, \] replacing $a$ by the number you find.

Your representations of the real numbers look fine to me. There is always controversy over what "whole numbers" should mean, and I would call \[ \{x \mid x = \ldots, -2, -1, 0, 1, 2, \ldots\} \] the set of integers. Note the slight difference between your expression and mine.