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| The functions sine, cosine and tangent of an angle are sometimes referred to as the primary or basic trigonometric functions. Their usual abbreviations are <math>\sin (\theta), \cos (\theta),</math> and <math>\tan (\theta),</math> respectively, where <math>\theta</math> denotes the angle. The parentheses around the argument of the functions are often omitted, e.g., <math>\sin \theta</math> and <math>\cos \theta,</math> if an interpretation is unambiguously possible. | | The functions sine, cosine and tangent of an angle are sometimes referred to as the primary or basic trigonometric functions. Their usual abbreviations are <math>\sin (\theta), \cos (\theta),</math> and <math>\tan (\theta),</math> respectively, where <math>\theta</math> denotes the angle. The parentheses around the argument of the functions are often omitted, e.g., <math>\sin \theta</math> and <math>\cos \theta,</math> if an interpretation is unambiguously possible. |
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− | The sine of an angle is defined, in the context of a [[right triangle]], as the ratio of the length of the side that is opposite to the angle divided by the length of the longest side of the triangle (the hypotenuse). | + | The sine of an angle is defined, in the context of a right triangle, as the ratio of the length of the side that is opposite to the angle divided by the length of the longest side of the triangle (the hypotenuse). |
| :<math>\sin\theta = \frac{\text{opposite}}{\text{hypotenuse}}.</math> | | :<math>\sin\theta = \frac{\text{opposite}}{\text{hypotenuse}}.</math> |
| The cosine of an angle in this context is the ratio of the length of the side that is adjacent to the angle divided by the length of the hypotenuse. | | The cosine of an angle in this context is the ratio of the length of the side that is adjacent to the angle divided by the length of the hypotenuse. |
The functions sine, cosine and tangent of an angle are sometimes referred to as the primary or basic trigonometric functions. Their usual abbreviations are and respectively, where denotes the angle. The parentheses around the argument of the functions are often omitted, e.g., and if an interpretation is unambiguously possible.
The sine of an angle is defined, in the context of a right triangle, as the ratio of the length of the side that is opposite to the angle divided by the length of the longest side of the triangle (the hypotenuse).
The cosine of an angle in this context is the ratio of the length of the side that is adjacent to the angle divided by the length of the hypotenuse.
The tangent of an angle in this context is the ratio of the length of the side that is opposite to the angle divided by the length of the side that is adjacent to the angle. This is the same as the ratio of the sine to the cosine of this angle, as can be seen by substituting the definitions of and from above:
The remaining trigonometric functions secant (), cosecant (), and cotangent () are defined as the reciprocal functions of cosine, sine, and tangent, respectively. Rarely, these are called the secondary trigonometric functions:
These definitions are sometimes referred to as ratio identities.
Inverse trigonometric functions
The inverse trigonometric functions are partial inverse functions for the trigonometric functions. For example, the inverse function for the sine, known as the inverse sine () or arcsine (arcsin or asin), satisfies
and
This article will denote the inverse of a trigonometric function by prefixing its name with "". The notation is shown in the table below.
Compositions of trig and inverse trig functions
[1]
Taking the multiplicative inverse of both sides of the each equation above results in the equations for
The right hand side of the formula above will always be flipped.
For example, the equation for is:
while the equations for
and
are:
Solutions to elementary trigonometric equations
The following table shows how inverse trigonometric functions may be used to solve equalities involving the six standard trigonometric functions.
It is assumed that the given values and all lie within appropriate ranges so that the relevant expressions below are well-defined.
In the table below, "for some Template:Nowrap" is just another way of saying "for some integer "
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if and only if |
Solution |
where...
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for some
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For example, if then for some While if then for some where is even if ; odd if The equations and have the same solutions as and respectively. In all equations above Template:Em for those just solved (i.e. except for / and /), for fixed and the integer in the solution's formula is uniquely determined by
Template:EqualOrNegativeIdenticalTrigonometricFunctionsSolutions
Other identities
These inverse trigonometric functions are related to one another by the formulas:
which hold whenever they are well-defined (that is, whenever
are in the domains of the relevant functions).
Aslo,[2]
Resources
↑ Template:Harvnb
↑ Wu, Rex H. "Proof Without Words: Euler's Arctangent Identity", Mathematics Magazine 77(3), June 2004, p. 189.