| Line 31: | Line 31: | ||
lets us calculate that <math>R</math> is <math>\pi/N</math> times the imaginary part of | lets us calculate that <math>R</math> is <math>\pi/N</math> times the imaginary part of | ||
| − | <math>\frac{1-\left(e^{i\pi/N}\right)^{N+1}}{1-e^{i\pi/N}}.</math> | + | <math>\frac{1-\left(e^{i\pi/N}\right)^{N+1}}{1-e^{i\pi/N}} -1.</math> |
Now | Now | ||
| Line 45: | Line 45: | ||
imaginary part of | imaginary part of | ||
| − | <math>\frac{\pi}{N}\frac{1+e^{i\pi/N}}{1-e^{i\pi/N}}.</math> | + | <math>\frac{\pi}{N}\left(\frac{1+e^{i\pi/N}}{1-e^{i\pi/N}}-1\right).</math> |
| + | |||
| + | which is equal to | ||
| + | |||
| + | <math>\frac{\pi}{N}\left(\frac{2e^{i\pi/N}}{1-e^{i\pi/N}}-1\right).</math> | ||
| + | |||
| + | Finally, use Euler's Identity and compute the imaginary part to get | ||
| + | |||
| + | <math>R=</math> | ||
Revision as of 12:28, 1 September 2011
We want to calculate
$ \int_0^\pi \sin x\ dx $
three days before we learn the Fundamental Theorem of Calculus, so our only tool is the limit of a Riemann sum.
So
$ \int_0^\pi \sin x\ dx\approx \sum_{n=1}^N \sin(n\pi/N)(\pi/N) $
when $ N $ is large.
Recall Euler's identity,
$ e^{i\theta}=\cos\theta + i\sin\theta. $
Hence, that Riemann sum $ R $ is the imaginary part of
$ (\pi/N)\sum_{n=1}^N e^{in\pi/N}. $
But
$ e^{in\pi/N}=\left(e^{i\pi/N}\right)^n, $
so $ R $ is just the imaginary part of a geometric sum.
The formula
$ 1+r+r^2+\dots+r^N = \frac{1-r^{N+1}}{1-r} $
lets us calculate that $ R $ is $ \pi/N $ times the imaginary part of
$ \frac{1-\left(e^{i\pi/N}\right)^{N+1}}{1-e^{i\pi/N}} -1. $
Now
$ \left(e^{i\pi/N}\right)^{N+1}= e^{i\pi + i\pi/N}= e^{i\pi}e^{i\pi/N}=-e^{i\pi/N} $
since
$ e^{i\pi}=\cos\pi+i\sin\pi=-1+0i=-1. $
Hence, we obtain that the Riemann sum is equal to the imaginary part of
$ \frac{\pi}{N}\left(\frac{1+e^{i\pi/N}}{1-e^{i\pi/N}}-1\right). $
which is equal to
$ \frac{\pi}{N}\left(\frac{2e^{i\pi/N}}{1-e^{i\pi/N}}-1\right). $
Finally, use Euler's Identity and compute the imaginary part to get
$ R= $
