Trig functions

Domain and Range

Based on Professor Leonard, Trig 8(Precalculus 81)

$f(\theta)$	domain	range
$\sin{\theta}$	$\Re$	$[1,1]$
$\cos{\theta}$	$\Re$	$[1,1]$
$\tan{\theta}$	$\theta\ne\frac{\pi}{2},\frac{3\pi}{2},\frac{5\pi}{2}, ... $	$(-\infty,\infty)$
$\csc{\theta}$	$\theta\ne0,\pi,2\pi,3\pi ... $	$(-\infty,-1]\space\cup\space[1, \infty)$
$\sec{\theta}$	$\theta\ne\frac{\pi}{2},\frac{3\pi}{2},\frac{5\pi}{2}, ... $	$(-\infty,-1]\space\cup\space[1, \infty)$
$\cot{\theta}$	$\theta\ne0,\pi,2\pi,3\pi ... $	$(-\infty,\infty)$

Periods and Related Identities

$f(\theta)$	period	related identity
$\sin(\theta)$	$2\pi$	$\sin(\theta\space\pm\space2\pi) = \sin(\theta)$
$\cos(\theta)$	$2\pi$	$\cos(\theta\space\pm\space2\pi) = \cos(\theta)$
$\tan(\theta)$	$\pi$	$\tan(\theta\space\pm\space\pi) = \tan(\theta)$
$\csc(\theta)$	$2\pi$	$\csc(\theta\space\pm\space2\pi) = \csc(\theta)$
$\sec(\theta)$	$2\pi$	$\sec(\theta\space\pm\space2\pi) = \sec(\theta)$
$\cot(\theta)$	$\pi$	$\cot(\theta\space\pm\space\pi) = \cot(\theta$)

Reciprocal Identities

(from Trig 9 precalc 82)

Because (for unit circle) $\sin\theta = y$ and $\csc\theta = \frac{1}{y}$, therefore $\csc\theta = \frac{1}{\sin\theta}$

Etc. for other recip functions. Easy. Skip

But then here’s equation for circle:

\[ x^2 + y^2 = r^2 \]

Looks like Pythagorean theorem, because it is! Can always inscribe a right triangle onto a circle this way.

So given: $\sin\theta = \frac{12}{13}$, find y, r, and x.

So y is 12, r = 13. OR can make it $y = \frac{12}{13}$ with a radius of one! Because with similar triangles, can multiply all our sides by same number to get a similar triangle in same proportion. Can therefore also multiply by 13 to get rid of fraction. For Pythagorean theorem, it’s better to stay with y = 12, r = 13.

So let’s find x (I did) $$ 13^2 = 169 \\ 12^2 = 144 \\ 169 - 144 = 25 = x^2 \\ \therefore x = \pm 5 $$

Important that $\pm$, because we’re taking a square root here. To know sign, we need two trig functions or quadrant info, because triangle can flip on y axis, putting it into quadrant II, so there – x is negative.

Once again, review, $\tan\theta = \frac{y}{x} = \frac{\sin\theta}{\cos\theta}$

\(f(\theta)\)	domain	range
\(\sin{\theta}\)	\(\Re\)	\([1,1]\)
\(\cos{\theta}\)	\(\Re\)	\([1,1]\)
\(\tan{\theta}\)	\(\theta\ne\frac{\pi}{2},\frac{3\pi}{2},\frac{5\pi}{2}, ... \)	\((-\infty,\infty)\)
\(\csc{\theta}\)	\(\theta\ne0,\pi,2\pi,3\pi ... \)	\((-\infty,-1]\space\cup\space[1, \infty)\)
\(\sec{\theta}\)	\(\theta\ne\frac{\pi}{2},\frac{3\pi}{2},\frac{5\pi}{2}, ... \)	\((-\infty,-1]\space\cup\space[1, \infty)\)
\(\cot{\theta}\)	\(\theta\ne0,\pi,2\pi,3\pi ... \)	\((-\infty,\infty)\)

\(f(\theta)\)	period	related identity
\(\sin(\theta)\)	\(2\pi\)	\(\sin(\theta\space\pm\space2\pi) = \sin(\theta)\)
\(\cos(\theta)\)	\(2\pi\)	\(\cos(\theta\space\pm\space2\pi) = \cos(\theta)\)
\(\tan(\theta)\)	\(\pi\)	\(\tan(\theta\space\pm\space\pi) = \tan(\theta)\)
\(\csc(\theta)\)	\(2\pi\)	\(\csc(\theta\space\pm\space2\pi) = \csc(\theta)\)
\(\sec(\theta)\)	\(2\pi\)	\(\sec(\theta\space\pm\space2\pi) = \sec(\theta)\)
\(\cot(\theta)\)	\(\pi\)	\(\cot(\theta\space\pm\space\pi) = \cot(\theta\))