Tangent half-angle substitution
The tangent half-angle substitution is a change of variables used for evaluating integrals, which converts a rational function of trigonometric functions of into an ordinary rational function of by setting. This is the one-dimensional stereographic projection of the unit circle parametrized by angle measure onto the real line. The general transformation formula is:
The tangent of half an angle is important in spherical trigonometry and was sometimes known in the 17th century as the half tangent or semi-tangent. Leonhard Euler used it to evaluate the integral in his 1768 integral calculus textbook, and Adrien-Marie Legendre described the general method in 1817.
The substitution is described in most integral calculus textbooks since the late 19th century, usually without any special name. It is known in Russia as the universal trigonometric substitution, and also known by variant names such as half-tangent substitution or half-angle substitution. It is sometimes misattributed as the Weierstrass substitution. Michael Spivak called it the "world's sneakiest substitution".
The substitution
Introducing a new variable sines and cosines can be expressed as rational functions of and can be expressed as the product of and a rational function of as follows:Similar expressions can be written for,,, and.
Derivation
Using the double-angle formulas and and introducing denominators equal to one by the Pythagorean identity results inFinally, since, differentiation rules imply
and thus
Examples
Antiderivative of cosecant
We can confirm the above result using a standard method of evaluating the cosecant integral by multiplying the numerator and denominator by and performing the substitution .These two answers are the same because
The secant integral may be evaluated in a similar manner.
A definite integral
We wish to evaluate the integral:A naïve approach splits the interval and applies the substitution. However, this substitution has a singularity at, which corresponds to a vertical asymptote. Therefore, the integral must be split at that point and handled carefully:
Note: The substitution maps to and to. The point corresponds to a vertical asymptote in, so the integral is evaluated as a limit around this point.
Alternatively, we can compute the indefinite integral first:
Using symmetry:
Thus, the value of the definite integral is:
Third example: both sine and cosine
ifGeometry
As x varies, the point winds repeatedly around the unit circle centered at . The pointgoes only once around the circle as t goes from −∞ to +∞, and never reaches the point , which is approached as a limit as t approaches ±∞. As t goes from −∞ to −1, the point determined by t goes through the part of the circle in the third quadrant, from to . As t goes from −1 to 0, the point follows the part of the circle in the fourth quadrant from to . As t goes from 0 to 1, the point follows the part of the circle in the first quadrant from to . Finally, as t goes from 1 to +∞, the point follows the part of the circle in the second quadrant from to .
Here is another geometric point of view. Draw the unit circle, and let P be the point. A line through P is determined by its slope. Furthermore, each of the lines intersects the unit circle in exactly two points, one of which is P. This determines a function from points on the unit circle to slopes. The trigonometric functions determine a function from angles to points on the unit circle, and by combining these two functions we have a function from angles to slopes.
Hyperbolic functions
As with other properties shared between the trigonometric functions and the hyperbolic functions, it is possible to use hyperbolic identities to construct a similar form of the substitution, :Similar expressions can be written for,,, and. Geometrically, this change of variables is a one-dimensional stereographic projection of the hyperbolic line onto the real interval, analogous to the Poincaré disk model of the hyperbolic plane.