calculus Calculus is the mathematics, mathematical study of continuous change, in the same way that geometry is the study of shape, and algebra is the study of generalizations of arithmetic operations. Originally called infinitesimal calculus or "the ...

, integration by parametric derivatives, also called parametric integration, is a method which uses known

Integrals In mathematics, an integral is the continuous analog of a sum, which is used to calculate areas, volumes, and their generalizations. Integration, the process of computing an integral, is one of the two fundamental operations of calculus,Int ...

to integrate derived functions. It is often used in Physics, and is similar to

integration by substitution In calculus, integration by substitution, also known as ''u''-substitution, reverse chain rule or change of variables, is a method for evaluating integrals and antiderivatives. It is the counterpart to the chain rule for differentiation, and c ...

Statement of the theorem

By using the

Leibniz integral rule In calculus, the Leibniz integral rule for differentiation under the integral sign, named after Gottfried Wilhelm Leibniz, states that for an integral of the form \int_^ f(x,t)\,dt, where -\infty < a(x), b(x) < \infty and the integrands ...

with the upper and lower bounds fixed we get that

\frac\left(\int_a^b f(x,t)dx\right)=\int_a^b \frac f(x,t)dx

It is also true for non-finite bounds.

Examples

Example One: Exponential Integral

For example, suppose we want to find the integral :

\int_0^\infty x^2 e^ \, dx.

Since this is a product of two functions that are simple to integrate separately, repeated

integration by parts In calculus, and more generally in mathematical analysis, integration by parts or partial integration is a process that finds the integral of a product of functions in terms of the integral of the product of their derivative and antiderivati ...

is certainly one way to evaluate it. However, we may also evaluate this by starting with a simpler integral and an added parameter, which in this case is ''t'' = 3: :

0^\infty = \left( \lim_ \frac \right) - \left( \frac \right) \\ & = 0 - \left( \frac \right) = \frac. \end

This converges only for ''t'' > 0, which is true of the desired integral. Now that we know :

\int_0^\infty e^ \, dx = \frac,

we can differentiate both sides twice with respect to ''t'' (not ''x'') in order to add the factor of ''x''² in the original integral. :

\begin
& \frac \int_0^\infty e^ \, dx = \frac \frac \\

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& \int_0^\infty \frac e^ \, dx = \frac \frac \\

& \int_0^\infty \frac \left (-x e^\right) \, dx = \frac \left(-\frac\right) \\

& \int_0^\infty x^2 e^ \, dx = \frac. \end This is the same form as the desired integral, where ''t'' = 3. Substituting that into the above equation gives the value: :

\int_0^\infty x^2 e^ \, dx = \frac = \frac.

Example Two: Gaussian Integral

Starting with the integral

\int^\infty_ e^dx=\frac

, taking the derivative with respect to ''t'' on both sides yields

\begin
&\frac\int^\infty_ e^dx=\frac\frac\\
&-\int^\infty_ x^2 e^ = -\fract^\\
&\int^\infty_ x^2e^= \fract^
\end

.
In general, taking the ''n''-th derivative with respect to ''t'' gives us

\int^\infty_ x^e^= \fract^

Example Three: A Polynomial

Using the classical

\int x^t dx=\frac

and taking the derivative with respect to ''t'' we get

\int \ln(x)x^t= \frac - \frac

Example Four: Sums

The method can also be applied to sums, as exemplified below.
Use the Weierstrass factorization of the sinh function:

\frac=\prod_^\infty \left(\frac\right)

.
Take the logarithm:

\ln(\sinh (z)) - \ln(z)=\sum_^\infty \ln\left(\frac\right)

.
Derive with respect to ''z'':

\coth(z) - \frac= \sum^\infty_\frac

.
Let

w=\frac

\frac\frac - \frac\frac=\sum^\infty_\frac

References

External links

WikiBooks: Parametric_Integration
Integral calculus {{mathanalysis-stub