Further curve sketching (1 Viewer)

Michael7 · Jan 22, 2018

Hi, could anyone please explain the reasoning to these sketches. I don't feel satisfied just memorising them, without knowing how they really work

y = -f(x) --> just change the y-coordinate of every point on the function y = f(x), i.e flip f(x) about the x-axis
y = f(-x) --> change the x-coordinate of every point on the original function
y = |f(x)| --> ?
y = f|(x)| ---> same y-value for the corresponding x-value. x>0 = f(x), x<0 = f(x)
|y| = f(x) --> this confuses me a lot

Thanks in advance!

fan96 · Jan 22, 2018

Imagine the graph of any function $y = f(x)$ on the Cartesian plane, for example $f(x) = x^2$ .

The graph of a function is a visualisation of the relationship between an input $x$ and an output $y$ .

1) $y = -f(x)$

This can be rewritten as $-y = f(x)$ . You're replacing $y$ with $-y$ , swapping the sign of each output. On a graph, this means that $(0, 1)$ becomes $(0, -1)$ , etc. If every $y$ value on the graph has its sign reversed, then you've basically flipped it across the $x$ axis.

2) $y = f(-x)$

Similar to 1), you are replacing $x$ with $-x$ . If you have two points $(1, 2)$ and $(-1, 4)$ on the graph, they will become $(-1, 2)$ and $(1, 4)$ after the swap. This flips the graph across the $y$ axis.

3) $y = |f(x)|$
Think of the graph $y=x$ here. Because of the absolute value function, any negative values of $f(x)$ will now become positive. Basically, you're flipping the graph (from down to up) across the $x$ axis ONLY where the $y$ value was negative before.

4) $y = f(|x|)$
Again, because of the absolute value function, any negative values of $x$ become positive before going into the function. So $f(-1) = f(1)$ , $f(-2) = f(2)$ , etc. You flip the graph from right to left across the $y$ axis.

5) $|y| = f(x)$
This is really tricky. It's really helpful to visualise this using an example. Look at the graphs of $y = x^2-1$ and $|y| = x^2-1$ .

Firstly, $|y| = f(x)$ is only defined for $x$ if $f(x)$ would have produced a positive number. $y$ doesn't exist if $|y| = -1$ , for example. So any $x$ values where $f(x)<0$ are removed.

So what happens when $f(x)$ is positive? Well if $|y| = f(x)$ , that means $y = \pm f(x), \, f(x) \geq 0$ . So for an $x$ value that exists on the graph, the $y$ value could be either $f(x)$ OR $-f(x)$ (incidentally, this means that $|y| = f(x)$ is not a function). This is the same as mirroring the remaining graph across the x-axis.

To summarise: start with $y = f(x)$ , exclude all values of $x$ for which $f(x)<0$ , and mirror what's left across the x-axis.

Michael7 · Jan 22, 2018

Thank you so much, i really appreciate it. Understood everything except for the last one. I'm a little confused

fan96 · Jan 22, 2018

Okay, let me elaborate then. We can rewrite the relation to make it a bit less confusing.

$|y| = f(x)$

Using one of the definitions of the absolute value function $|k| = \sqrt {k^2}$ ,

$\sqrt{y^2} = f(x)$

$y^2 = f(x)^2, \, f(x) > 0$

(when we square both sides, we unintentionally define the relation for negative values of $f(x)$ - to fix that, we can restrict the domain of the resulting relation)

We end up with

$y =\pm f(x), \, f(x) > 0$

Which is equivalent to combining these two functions:

$y = f(x), \, f(x) > 0$

$y = -f(x), \, f(x) > 0$
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Basically, the takeaway is that

$|y| = f(x)$ is the same thing as $y =\pm f(x), \, f(x) > 0$
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That means for every (valid) $x$ value you input, the output $y$ value is both $f(x)$ AND $-f(x)$

Here's an example with $f(x) = x^2 - 1$

Further curve sketching (1 Viewer)

Michael7

New Member

fan96

617 pages

Michael7

New Member

fan96

617 pages

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