3.9 KiB
An identity is an equation that is true for all values of the variable for which the expressions in the equation are defined.
Trigonometric Identities
All of the following only apply when the denominator is not equal to zero.
tan \theta = \frac{y}{x}
Because the following are inverses of their counterparts, you only need to remember the equivalents for sin
, cos
, and tan
, then just find the inverse by taking 1/v
.
Base Identity | Inverse Identity | Alternate Identities | Alternate Inverse Identities |
---|---|---|---|
sin\theta = y
|
csc\theta = \frac{1}{y}
|
csc\theta = \frac{1}{sin\theta}
|
|
cos\theta = x
|
sec \theta = \frac{1}{x}
|
sec\theta = \frac{1}{cos\theta}
|
|
tan\theta = \frac{y}{x}
|
cot\theta = \frac{x}{y}
|
tan\theta = \frac{sin\theta}{cos\theta}
|
cot\theta = \frac{1}{tan\theta} = \frac{cos\theta}{sin{\theta}}
|
Pythagorean Identities
The Pythagorean identity expresses the Pythagorean theorem in terms of trigonometric functions. It's a basic relation between the sine and cosine functions.
sin^2 \theta + cos^2 \theta = 1
There are more forms that are useful, but they can be derived from the above formula:
1 + tan^2\theta = sec^2\theta
cot^2 \theta + 1 = csc^2\theta
Even and Odd Identities
- A function is even if
f(-x) = f(x)
. - A function is odd if
f(-x) = -f(x)
- Cosine and secant are even
- Sine, tangent, cosecant, and cotangent are odd.
Examples
Even and Odd Functions
If
cot\theta = -\sqrt{3}
, what iscot(-\theta)
?
cot
is an odd function, and so cot(-\theta) = \sqrt{3}
Simplifying Using Identities
Simplify
\frac{sin\theta}{cos\theta}
- The above equation can be split into two components
\frac{sin\theta}{cos\theta} = \frac{sin\theta}{1} * \frac{1}{csc\theta}
- Referring to the list of trig identities, we know that
\frac{1}{csc\theta}
is equal tosin\theta
.
\frac{sin\theta}{1} * \frac{1}{csc\theta} = sin\theta * sin\theta
- Simplifying further, we get:
sin^2\theta
Finding all values using identities
If sec\theta = -\frac{25}{7}
and 0 < \theta < \pi
, find the values of the other 5 trig functions:
- To find
tan\theta
, we can use the trig identity1 + tan^2\theta = sec^2\theta
:
1 + tan^2\theta = (-\frac{25}{7})^2
Shuffling things around, we get this:
tan^2\theta = \frac{625}{49} - 1
Performing that subtraction gives us this:
\frac{625}{49} - \frac{49}{49} = \frac{576}{49} = tan^2\theta
You can get rid of the exponent:
\sqrt{\frac{576}{49}} = tan\theta
\sqrt{576} = 24
and \sqrt{49} = 7
, so:
tan\theta = \frac{24}{7}
-
To find
cos\theta
, becausesec
is the inverse ofcos
, we can use the identitysec\theta = \frac{1}{cos\theta}
:cos\theta = -\frac{7}{25}
-
To find
sin\theta
, we can use the trig identitysin^2\theta + cos^2\theta = 1
:
sin^2\theta + (-\frac{7}{25}) = 1
Rearranging, we get:
1 - (-\frac{7}{25})^2 = sin^2\theta
Applying the exponent gives us \frac{49}{625}
, so we can do this:
\frac{625}{625} - \frac{49}{625} = \frac{576}{625} = sin^2\theta
Getting rid of the exponent:
\sqrt{\frac{576}{625}} = \frac{24}{25} = sin\theta
From there, you can find the rest of the identities fairly easily.
Simplifying trig expressions using identities
Given the difference of square formula:
a^2 - b^2 = (a-b)(a+b)
Examples
Simplify \tan\theta\sin\theta + \cos\theta
:
- $\frac{\tan\theta\sin\theta}{\sin\theta} + \frac{cos\theta}\frac{sin}