Trigonometry Arc Length Problem

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Euler2718
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First I'd just like to point out that I'm taking calculus and advance pre-calculus simultaneously (kind of a stupid system) and this is a problem in the pre-calc.

1. Homework Statement


IMG_3151.JPG


2. Homework Equations


Let 'a' be arc length.

[tex]a=\theta r[/tex]

[tex]a = \int_{a}^{b} \sqrt{1+[f'(x)]^{2}} dx[/tex]

3. The Attempt at a Solution

The lecture on arc length wasn't even a lecture. Merely a hand out of the chapter summery, not to be touched again. I saw no central angle so [tex]a=\theta r[/tex] seems to be out of the question. This seemed to be an unusual problem, so I used Pythagoras after a while. I went

[tex]( \Delta x )^{2} + (\Delta y)^{2} = a^{2}[/tex]

This yields the arc length to [tex]\sqrt{8}[/tex] units.

I confirmed this with the integration for arc length. But I'm really not at the level of arc length integration yet. I can do basic integration only (I skipped ahead in the course a bit). Via wolfram alpha:

[tex]\int_{-8}^{-6} 10\sqrt{\frac{1}{100-x^{2}}} dx = 10\sin ^{-1}\left(\frac{7}{25}\right) \approx 2.83794[/tex]

Which is pretty much [tex]\sqrt{8}[/tex] So really, my question is if there is another more formal way to approach this problem using trigonometric concepts to arrive at an answer.

Thank you in advance.
 
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phinds said:
Can you figure out the angle AQB?

Ahhh. Using the right triangles no doubt. I'll give it a go. Thanks.
 
Problems involving derivatives or integrals should be posted in the calculus section, not in the precalculus section. I have moved this thread.
 
Mark44 said:
Problems involving derivatives or integrals should be posted in the calculus section, not in the precalculus section. I have moved this thread.

Sorry. I merely included the calculus to show what I used to compute the answer, as it was technically part of my attempt.
 
Pretty sure I got it now! Thank you phinds for the tip. I calculated the central angle to be 16.3°, and used the arc length equation from there. It comes out to 2.8 units, which is what the Pythagorean approximation and the integration came to.