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I'm being asked to find the arc length of $y=\sin( x)$ for $[0, \frac{\pi}{2}]$ using $M_8$.

I've determined that $y\prime^2=\cos^2x$. So, using the formula for arc length, I get $\sqrt{1+\cos^2x}$ as my function.

Now, they want me to evaluate this using $M_8$, so I end up with $8$ midpoints from $\frac{\pi}{32}$ to $\frac{15\pi}{32}$ moving up in increments of $\frac{\pi}{16}$.

Also, I know that $\Delta{x} = \frac{\pi}{16}$. So, I end up with this estimated integral:

$\frac{\pi}{16}\left(\sqrt{1+\cos^2(\tfrac{\pi}{32})} + \sqrt{1+\cos^2(\tfrac{3\pi}{32})} + ... \sqrt{1+\cos^2(\tfrac{15\pi}{32})}\right) = 1.91009889$

Please feel free to correct any errors here.

My question, however, has to do with simplifying this answer using trig. I would assume that there's a fancy way to do this, rather than just handing in the answer $1.91009889$ (though the prof will accept this).

I'd like to sharpen my trig skills, so I figured this was a great chance.

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    @GFauxPas We were asked to find the arc length of the curve over the interval using either the Trapezoidal Rule ($T_N$), Midpoint Rule ($M_N$), or Simposon's Rule ($S_N$). $M_N$ is interpreted as either the sum of the areas of the midpoint rectangles or the sum of the tangential trapezoids.2016-10-24

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Offhand, not much comes to mind with regard to $\sqrt{1+\cos^2x}$, but $\cos\frac{k\pi}{2^n}$ can be evaluated exactly using the half-angle identity $\cos\frac{x}{2}=\pm\sqrt{\frac{1+\cos x}{2}}$ (choose + or – based on the value of $\frac{x}{2}$) repeatedly.

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    Rogawski 1429210737. This question was 8.1.12.2011-03-10