Question 1

Shouldn't it be -3 from the left, so -3^- ?

Accepted Answer

It also took me some time to understand. Basically, he is shortening the stuff.

When you take the limit of h(x) from the right-hand side (x=>1^+) you get -2.

When you take the limit of h(x) from the right-hand side (x=>1^-) you get -3.

After that when you do the same for g(h(x)) from the left and right-hand side for h(x=>-2), you will get 3 for both hand sides.

Same for the h(x)=>-3, both left and right-hand sides will be the same, with the answer of 3.

instead of doing the whole stuff he just did the desired and required stuff.

Question 2

It is confusing from 3:05 while taking the LH limit of g(h(x)) as x app-1^- and equating to LH limit of g(h(x)) as h(x) app -3 #should it be -3^- or -3^+. Please answer.

Accepted Answer

It also took me a while to figure out:

When you're thinking about what h(x) is approaching, you are looking at the *y (vertical) axis* . 
It'd be as if you tilt the whole image by 90º (to the right), or tilt your head to the left like an owl. And so, on the y axis: 
"right" (+) is the upper side of the graph, 
"left" (-) is the lower side of the graph.

So if you look at this graph, h(x) is approaching _both_ -2 and -3 from the _right_ / _upper_ (+) side. 
You don't have to look at _both_ + and - for each. You only have to figure out where it's approaching _from_.

Hope that helps!

Question 3

Stuck at h(x) -> -3+, checked the comments here and on YT, people say its + and not - because we're looking at the Y values. I thinks that's right but how do we know which value to look at? In previous videos I was under the impression that we considered the X axis when determining right hand or left hand?

Accepted Answer

I think considering the Y-axis is just for when we are doing composite functions because in a composite function, we are taking the *outputs/y-values* of the *internal function* and then using them as *inputs/x-values* of the *external function*.

For other operations such as addition, subtraction, multiplication and division, the y-values *remained* as y-values, they never became x-values for another function which is why it was a lot more straight forward.

Here are steps that I found from someone else (I can't seem to find their comment anymore) that really helped me understand what was going on:

1) Take the limit of the function h(x) as x -> -1 from the right

2) The *OUTPUT* of that function will be -1.9, -1.99, -1.999...

3) That sequence of numbers will serve as the *INPUT* for g(x): g(-1.9), g(-1.99), g(-1.999)...

4) Following that same series of inputs in g(x) as x -> -2 means you get closer to -2 from the *RIGHT/POSITIVE* side of the graph

5) Do the same thing for the left side and. we see that x seems to be approaching -3 from both sides

Hope this helps and If I made a mistake anywhere please be sure to correct me!

Question 4

After an initial confusion, I think I have understood the procedure, but I would like confirmation that I have done it right, because I am not sure.
Towards the end, Sal calculates the limit of h(x) as x approaches -1 from the left. That is easy: -3.
But then the complicated thing comes, because to find the corresponding limit of g(x), looks for the limit from the right (!). What I think is the following:
We have -3 we got from the previous step. But if we look at the graph, the values of y are diminishing as they approach that point. That is, -3 is approximated from above.
Now, when we plug this value in the x-axis of g(x), we need to do it in the same way, that is, from above, i.e., from the values greater than -3, which means that we are approximating from the right.
Can anybody confirm that I have understood it right? Thanks.

Accepted Answer

Correct. I find it healthier to think of from the right as "values above x " i.e. x⁺ and from the left as "values below x " i.e. x⁻.

Question 5

I'm in 6th grade, so this is taking a bit to comprehend.

Accepted Answer

`h(x)` has no limit as it approaches the x-position of -1. From the left side, the function seems to be approaching y = -3, while from the left side, the function seems to be approaching y = -2. Since the "left and right limits" don't match, *the function doesn't have one single limit*.

_However_, we are not focusing on the limit of `h(x)` by itself, we are focusing on the composite function `f(h(x))`. The limit of `h(x)` from the left side is -3, so plugging that into our function `f(h(x))` would result in `f(-3)` from the left side, since `h(x)` = 3 (as the function approaches -1 from the left).

The limit of `h(x)` from the right side is -2, so that would be `f(-2)`. In the graph `f(x)`, the limit of f as it approaches -2 and the limit of `f(x)` as it approaches -3 are both equal to 3, so the limit of the composite function `f(h(x))` is equal to three.

I hope you understand! If I made anything unclear, please let me know. Also, nice job taking the initiative and learning Calculus in 6th grade (I am learning some of it early for fun)!

Question 6

What happens when you get two different answers for both the g(h(x))?

Accepted Answer

Then the limit does not exist

Question 7

When solving for the composite limit, he made both of the limit tests right handed limit tests when it came to testing the limit of g(x). Is that because they have to be the same direction in order to see if they're truly the same value? Or is that some other thing I should be thinking about? (If my question doesn't make sense, I'm asking why he used right bound limit tests for both the left and right bound limit tests after he found the value of h(x) under the the limit x->-1)

Accepted Answer

Hey Tyler, I think I had the same question as you. If you're confused about why he did the lim h(x) -> -2+ then the lim h(x) -> -3+ (and thought they were both right handed limits) *the confusion happens because lim h(x) -> some value is not the same as lim x -> some value*. To my understanding when you have a limit h(x) -> some value, it's the limit when the *Y-value* of h(x) approaches some value, not the x value.

Basically the function g(h(x)) is taking the y-values of h(x) and plugging them into g(x). Let's take the example lim x -> -1+ g(h(x)):

Firstly, you plug in x values getting infinitely close to -1 from the right into h(x). So that would be -0.9, -0.99, -0.999 etc. You see that the values will approach -2 from *above*, hence the notation that h(x) -> -2+.

*I think you are able to change the original lim x-> -1+ g(h(x)) to lim h(x) -> -2+ g(h(x)) for that same reason*. You are taking the x value, putting it into h(x), and the outputs (y-values) approach -2+(from above) are being inputted into g(x). Therefore, you take those outputted y-values and sub them into g(x) (like you would for any composite function). It would look something like this

g(-1.9) g(-1.99) g(-1.9999) getting infinitely close to g(-2) from values *greater* than -2 as possible, _because that's how the outputs for h(x) are behaving when you do h(-0.9) h(-0.99) etc._ keep in mind the original lim is x-> -1+ g(h(x)). All of that gives the final answer of 3.

The ^+ on the -2 and -3 denote the behavior (above and below) of the y-values of h(x).

I'm not sure if that's exactly correct but that's how I've understood it so far.

Question 8

This is confusing. Inputting something that does not exist into a function should yield something that does not exist. How come it actually exists?

Accepted Answer

The meaning of a limit that DNE just means that the one-sided limits are different i.e. value of the function as x approaches a from below is different from the value of the function as x approach a from values above a. But this is only true for the inner function h(x).

We know that the lim x→-1 g(h(x)) exists and is true so long if lim x→-1⁺ g(h(x)) = lim x→-1⁻ g(h(x)). We just need to prove that the one-sided limits for the composite function are the same for the limit of the composite function to exist.
The composite function is taking the output of the inner function as input.
As x→-1⁺ for h(x), the output h(x)→-2⁺. Plugging this h(x) output *as the x-input* into g(x), lim h(x)→-2⁺ g(h(x)) = 3

As x→-1⁻ for h(x), h(x)→-3⁺. Plugging this h(x) output *as the x-input* into g(x), lim h(x)→-3⁺ g(h(x)) = 3

To visualise this, I found it very helpful to visualise this on the graphs. Look at the video again, notice Sal uses the arrows in both h(x) and g(x). 
As x→-1⁺, draw an arrow of h(x)→-2⁺. Now look at g(x) which takes h(x) as its x-input. 
For g(x), as x (now x is h(x)) → -2⁺, g(x) = 3.
Now go back to h(x). As x→-1⁻, limit h(x) → -3⁻ and draw an arrow as h(x) → -3⁻.
Now go to g(x) which takes h(x) as its x-input, as x (now is equal to h(x)) → -3⁺, g(x) = 3

So we have proven that lim x→-1 g(h(x)) exists and is equivalent to: lim x→-1⁺ g(h(x)) = lim x→-1⁻ g(h(x)) because the one-sided limits are the same.

Avoid being overly fixated on the thought that the limit that DNE. DNE just means the one-sided limits are different. Just because the one-sided limits are different for one function does not mean that the one-sided limits of another function (which could take these different one-sided limits as input) are different. 
Thus, even if a limit does not exist (one-sided limits are different) for one function, does not mean that the limit for another function who takes these different one-sided limits as input, does not exist.

Course: Differential Calculus > Unit 1

Limits of composite functions: internal limit doesn't exist

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