Why is $1 - 2\cos^2(\frac{\pi n} {4})$ the same as $ -\cos(\frac{\pi n} {2}) $
I think the 1 in here, I can just neglect when I look at borders from $[-\infty , \infty]$.
But what's going on with the cosine in here?
Why is $1 - 2\cos^2(\frac{\pi n} {4})$ the same as $ -\cos(\frac{\pi n} {2}) $
I think the 1 in here, I can just neglect when I look at borders from $[-\infty , \infty]$.
But what's going on with the cosine in here?
If you know the double angle formula $\cos 2x=2\cos^2 x-1,$ then the result follows immediately. Just let $x=\frac{\pi n}{4}$.
The double-angle formula follows from the "cosine of a sum" formula $\cos(x+y)=\cos x\cos y-\sin x\sin y.$ Put $x=y$, and you get $\cos 2x=\cos^2 x-\sin^2 x$. But $\sin^2 x=1-\cos^2 x$, so $\cos^2 x -\sin^2 x=\cos^2 x-(1-\cos^2 x)=2\cos^2 x-1$.
Another way: However, you do not even need the double angle formula to deal with this particular problem. The cosine function has period $2\pi$, so all you need to do is to calculate both sides for $n=0, 1, 2, \dots, 7$. The individual calculations are not difficult. For example, if $n=1$, then $\cos(\pi n/4)=\cos(\pi/4)=1/\sqrt{2}$. So $1-2\cos^2(\pi/4)=1-2/2=0$. Note that $-\cos(\pi/2)=0$, so the result is correct for $n=1$. Seven more to go.
But not really $7$. For $\cos(2\pi-x)=\cos x$, so we don't have to check beyond $n=4$.
This follows by the ordinary addition formula for the cosine function $\cos(x+y)=\cos(x)\cos(y)-\sin(x)\sin(y)$ and by noting that $1=\sin^2(x)+\cos^2(x)$
i.e.
$1-2\cos^2(x)=\sin^2(x)-\cos^2(x)=-\cos(2x)$ Lastly plug in $x=\frac{\pi n}{4}$