Trigonometry/Double-Angle Formulas

Template:TrigBoxOpen Double angle formulae for cos and sine:

${\displaystyle \cos (2a)=2{\cos }^2(a)-1}$

${\displaystyle \sin (2a)=2\cos (a)\sin (a)}$

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The Double-Angle formulas express the cosine and sine of twice an angle in terms of the cosine and sine of the original angle. We are going to derive them from the addition formulas for sine and cosine. The formulae are:

${\displaystyle \cos (2a)=2{\cos }^2(a)-1}$

and

${\displaystyle \sin (2a)=2\cos (a)\sin (a)}$

It is well worth practising the derivation so that you can do it quickly and easily. Then you will not need to remember the formulae, since you can get them quickly from the addition formulas for sine and cosine. It is also good to practice the derivation because being more fluent with the algebra will make you better at other algebra used with trigonometry.

Template:ExerciseRobox Did we make a typo in these formulae? Check they at least make sense.

• We know that ${\displaystyle \sin (0)=0}$ and ${\displaystyle \cos (0)=1}$ . Try those values out. Do the formulae work?
• ${\displaystyle -1\le \cos (\theta )\le 1}$ and ${\displaystyle -1\le \sin (\theta )\le 1}$ . Are the formulae consistent with that?
• Make up your own additional 'spot check' to check the formulae

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Template:ExampleRobox If we put ${\displaystyle \alpha =2a}$ we immediately get

${\displaystyle \cos (\alpha )=2{\cos }^2\left(\frac{\alpha }{2}\right)-1}$

Check it. Do you agree? Or rearranging:

${\displaystyle \cos \left(\frac{\alpha }{2}\right)=\sqrt{\frac{\cos (\alpha )+1}{2}}}$

So, if we know the cosine of ${\displaystyle 90^{\circ }}$ (we do, it is zero), we can compute the cosine of ${\displaystyle 45^{\circ }}$ and ${\displaystyle 22.5^{\circ }}$ and ${\displaystyle 11.25^{\circ }}$ and so on.

${\displaystyle \cos (45^{\circ })=\sqrt{\frac{\cos (90^{\circ })+1}{2}}=\sqrt{\frac{1}{2}}}$

${\displaystyle \cos (22.5^{\circ })=\sqrt{\frac{\cos (45^{\circ })+1}{2}}=\sqrt{\frac{\sqrt{\frac{1}{2}}+1}{2}}}$

${\displaystyle \cos (11.25^{\circ })=\sqrt{\frac{\cos (22.5^{\circ })+1}{2}}=\sqrt{\frac{\sqrt{\frac{\sqrt{\frac{1}{2}}+1}{2}}+1}{2}}}$

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We'll prove the double angle formulae from the addition formulae. Recall that:

${\displaystyle \cos (a+b)=\cos (a)\cos (b)-\sin (a)\sin (b)}$

Putting ${\displaystyle b=a}$ in the above formula yields:

${\displaystyle \cos (2a)}$	${\displaystyle =\cos (a+a)}$
	${\displaystyle =\cos (a)\cos (a)-\sin (a)\sin (a)}$
	${\displaystyle ={\cos }^2(a)-{\sin }^2(a)}$

So:

${\displaystyle \cos (2a)={\cos }^2(a)-{\sin }^2(a)}$

Compare this with the "Pythagorean Theorem" expressed in terms of sine and cosine. Notice the double angle formula above has a minus not a plus, otherwise it would be saying ${\displaystyle \cos (2a)=1}$ , which would mean cos was 1 for all values of t, which we know is not true.

The formula

${\displaystyle \cos (2a)={\cos }^2(a)-{\sin }^2(a)}$

isn't yet quite where we want it. We want to get rid of the sine term and express it all in terms of cosine. To do that we use the disguised "Pythagorean Theorem".

${\displaystyle {\cos }^2(a)+{\sin }^2(a)=1}$

which is the same as:

${\displaystyle -{\sin }^2(a)={\cos }^2(a)-1}$

so

${\displaystyle \cos (2a)={\cos }^2(a)-{\sin }^2(a)={\cos }^2(a)+{\cos }^2(a)-1=2{\cos }^2(a)-1}$

so

${\displaystyle \cos (2a)=2{\cos }^2(a)-1}$

which is what we wanted.

We could, if we had preferred, have used the disguised Pythagorean theorem to replace the ${\displaystyle {\cos }^2(a)}$ in terms of ${\displaystyle {\sin }^2(a)}$

Template:ExerciseRobox Do that now, in other words express:

${\displaystyle \cos (2a)}$

in terms of ${\displaystyle \sin (a)}$

• Check your answer, particularly to make sure that you have all the minus signs right.

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Now we will get the double angle formula for sine, this time using the addition formula for sine.

${\displaystyle \sin (a+b)=\sin (a)\cos (b)+\sin (b)\cos (a)}$

Check that we've quoted the addition formula correctly, and then put ${\displaystyle b=a}$ in the above

${\displaystyle \sin (2a)}$	${\displaystyle =\sin (a+a)}$
	${\displaystyle =\sin (a)\cos (a)+\sin (a)\cos (a)}$
	${\displaystyle =2\cos (a)\sin (a)}$

So:

${\displaystyle \sin (2a)=2\cos (a)\sin (a)}$

Unlike the formula for cosine the substitutions to get ${\displaystyle \sin (2a)}$ just in terms of ${\displaystyle \sin (a)}$ would involve square roots, so we're not going to do that. The above formula is usually the nicest form to work with.

Using the above procedures twice, and the Pythagorean theorem where appropriate, we find

${\displaystyle \sin (3a)=3\sin (a)-4{\sin }^3(a)}$

${\displaystyle \cos (3a)=4{\cos }^3(a)-3\cos (a)}$

By repeating the procedure, we can find formulae for ${\displaystyle \sin (na)}$ and ${\displaystyle \cos (na)}$ for any integer n. The formulas do however get rather long.

It is not really worthwhile remembering these formulae. They are not used often, and can either be looked up in tables of formulae or calculated when you need them. It is quite good for practising algebra to derive them yourself, so....

Template:ExerciseRobox Derive the formulas for ${\displaystyle \sin (3\alpha )}$ and ${\displaystyle \cos (3\alpha )}$ yourself.

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By using ${\displaystyle \tan (a)=\frac{\sin (a)}{\cos (a)}}$ , it can be worked out that:

${\displaystyle \tan (2a)=\frac{2\tan (a)}{1-{\tan }^2(a)}}$

${\displaystyle \tan (3a)=\frac{3\tan (a)-{\tan }^3(a)}{1-3{\tan }^2(a)}}$

Like the formulas for ${\displaystyle \sin (3\alpha )}$ and ${\displaystyle \cos (3\alpha )}$ , these formulae aren't often useful, but again it is good to be able to work them out yourself.

Template:ExerciseRobox Derive the formulas for ${\displaystyle \tan (2x)}$ and ${\displaystyle \tan (3x)}$ yourself.

• If you don't get 'the right answer,' don't panic. It takes time and practice to become fluent at algebraic manipulations. Here, where you know the right answer, you can work through your steps and try and find for yourself where you went wrong. Very often it is a sign error somewhere, adding a value instead of subtracting, and then everything from that point on is wrong. You can use the trick of putting in actual values for ${\displaystyle x}$ (and calculating with a calculator) to check for the place where the first error creeps in.

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