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$2\cos{x} - \cos{}2x = \dfrac{5}{4}$

Find all values for $x$ in the interval [$0$°, $360$°]

Going from this equation I arrived at (by way of quadratic addition)

$\cos{x} = \dfrac{1+\sqrt{2}}{2\sqrt{2}}$

which I translated to

$x = 31.3997$° (approximately)

However, there are three other solutions ($328$°, $81$° and $278$°, all with fractions after the decimal point). How do I find these values, and more generally, how do I find all possible values for $x$ between $0$° and $360$°?

2 Answers 2

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$2\cos x -(-1+2\cos^2 x)=\frac{5}{4}$

$2\cos^2 x-2\cos x +\frac{1}{4}=0$

And I get:

$\cos{x} = \frac{2 \pm \sqrt{2}}{4}$

In general, solving an equation for $\cos x$ and getting $\cos x=a$, your final answer would be something like:

$x=2k\pi \pm a; k \in \mathbb{Z}$

And you need to replace $k$ to get the appropriate answers in the interval. For instance, for $k=1$:

$x=2\pi \pm \cos^{-1} \left ( \frac{2 \pm \sqrt{2}}{4} \right )$

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    @MiroslavCetojevic: An arbitrary integer number, such as 0, $1$, $2$, $\dots$.2012-05-28
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Using the formula $\cos2x=2\cos^2x-1$ we get the equivalent equation $2\cos x-2\cos^2x+1=\frac54$ which simplifies to $\cos^2x-\cos x+\frac18=0$ This is a quadratic equation in $\cos x$, so we can solve it the usual way to get two solutions:

$\cos x=\frac{2\pm\sqrt{2}}{4}\qquad(*)$

Now, for each of these solutions we get the unique solution lying on the interval $[0°,180°]$ using $\arccos$, so the solutions lying on the interval $[0°,180°]$ are exactly:

$x_{1,2}=\arccos\left(\frac{2\pm\sqrt{2}}{4}\right)$

Now, if you remember what the graph of $\cos$ looks like, you'll see, that on $[180°,360°]$, the graph is a mirror image of the graph above $[0°,180°]$. Therefore, we will get two more solutions of (*) by subtracting the two solutions we already have from $360°$, i.e.

$x_3=360°-x_1\\x_4=360°-x_2$

This is a complete list of solutions.