Formulário de Integrais

Considerando $a$ e $\text{C}$ como números reais ou constantes, $u$ é a função de $x$ e $u'$ é a derivada de $u$ .

Formas básicas e propriedades de integrais

$\displaystyle \int \ u^{n} \cdot du = \cfrac{u^{(n+1)}}{n+1} + \text{C},\qquad n \neq -1$
$\displaystyle \int \ du = u + \text{C}$
$\displaystyle \int a \cdot (u^{n}) \cdot du =$ $\displaystyle a \cdot \int u^{n} \cdot du = a \cdot \Bigg ( \cfrac{u^{(n + 1)}}{n + 1} \Bigg ) + \text{C}, \qquad$ $n \neq -1$
$\displaystyle \int \cfrac{du}{u} = \ln |u| + \text{C}$
$\displaystyle \int e^{u} \cdot du = e^{u} + \text{C}$
$\displaystyle \int a^{u} \cdot du = \cfrac{a^{u}}{\ln a} + \text{C}$

A integral de uma adição/subtração é igual à adição/subtração das integrais

$\displaystyle \int \big (u^{n} \pm u^{n\pm 1} \pm u^{n\pm 2} \big ) \cdot du =$ $\displaystyle \int u^{n} \cdot du \pm \int u^{n \pm 1} \cdot du \pm \int u^{n\pm 2} \cdot du$

Fórmulas de integrais trigonométricas

Integral do seno

$\displaystyle \int \sin u \cdot du = - \cos u + \text{C}$

Integral do cosseno

$\displaystyle \int \cos u \cdot du = \sin u + \text{C}$

Integral do tangente

$\displaystyle \int \tan u \cdot du =$ $\ln |\sec u| + \text{C}$ $= -\ln |\cos u| + \text{C}$

Integral do cotangente

$\displaystyle \int \cot u \cdot du =$ $\ln |\sin u|+ \text{C}$

Integral do secante

$\displaystyle \int \sec u \cdot du =$ $\log\left(\sec u + \tan u\right)+ \text{C}$

Integral do cossecante

$\displaystyle \int \csc u \cdot du =$ $\ln |\csc u - \cot u|+ \text{C} =$ $-\csc u \cdot \cot u + \text{C} =$ $-\log\left( \cot u + \csc u\right)$

Integral de secante por tangente

$\displaystyle \int \sec u \cdot \tan u \cdot du =$ $\sec u + \text{C}$

Integral de cossecante por cotangente

$\displaystyle \int \csc u \cdot \cot u \cdot du =$ $- \csc u + \text{C}$

$\displaystyle \int \cfrac{du}{u^{2} + a^{2}} =$ $\cfrac{1}{a} \cdot \tan^{-1} \cfrac{u}{a} + \text{C}$
$\displaystyle \int \cfrac{du}{u^{2} - a^{2}} =$ $\cfrac{1}{2 \cdot a} \cdot \ln \bigg | \cfrac{u - a}{u + a} \bigg | + \text{C}$
$\displaystyle \int \cfrac{du}{a^{2} - u^{2}} =$ $\cfrac{1}{2a} \cdot \ln \bigg |\cfrac{u + a}{u - a} \bigg | + \text{C}$
$\displaystyle \int \cfrac{du}{\sqrt{a^{2} - u^{2}}} =$ $\sin^{-1} \cfrac{u}{a} + \text{C}, \qquad a > 0$
$\displaystyle \int \cfrac{du}{\sqrt{u^{2} - a^{2}}} =$ $\ln \big ( u + \sqrt{u^{2} - a^{2}} \big ) + \text{C}$
$\displaystyle \int \cfrac{du}{\sqrt{u^{2} + a^{2}}} =$ $\ln \big ( u + \sqrt{u^{2} + a^{2}} \big ) + \text{C}$ $= \sinh^{-1} \cfrac{u}{a} + \text{C}$
$\displaystyle \int \cfrac{du}{u \cdot \sqrt{u^{2} - a^{2}}} =$ $\cfrac{1}{a} \cdot \sec^{-1} \bigg | \cfrac{u}{a} \bigg | + \text{C}$
$\displaystyle \int \cfrac{du}{u \cdot \sqrt{u^{2} + a^{2}}} =$ $- \cfrac{1}{a} \cdot \ln \Bigg ( \cfrac{a + \sqrt{u^{2} + a^{2}}}{u} \Bigg ) + \text{C}$
$\displaystyle \int \cfrac{du}{u \cdot \sqrt{a^{2} - u^{2}}} =$ $- \cfrac{1}{a} \cdot \ln \Bigg ( \cfrac{a + \sqrt{a^{2} - u^{2}}}{u} \Bigg ) + \text{C}$

Fórmula de integração por partes

$\displaystyle \int u \cdot dv = u \cdot v - \int v \cdot du$

Fórmulas integrais trigonométricas

Integral do seno quadrado

$\displaystyle \int \sin^{2}u \cdot du =$ $\cfrac{1}{2} \cdot u - \cfrac{1}{4} \cdot \sin (2u) + \text{C} =$ $\cfrac{1}{2} \cdot (u - \sin u \cdot \cos u) + \text{C}$

Integral de cosseno quadrado

$\displaystyle \int \cos^{2}u \cdot du =$ $\cfrac{1}{2} \cdot u + \cfrac{1}{4} \cdot \sin(2u) + \text{C}$ $= \cfrac{1}{2} \cdot (u + \sin u \cdot \cos u)$

Integral da tangente ao quadrado

$\displaystyle \int \tan^{2}u \cdot du =$ $\tan u - u + \text{C}$

Integral de cotangente ao quadrado

$\displaystyle \int \cot^{2}u \cdot du =$ $- \cot u - u + \text{C}$

Integral da secante ao quadrado

$\displaystyle \int \sec^{2}u \cdot du =$ $\tan u + \text{C}$

Integral da cossecante ao quadrado

$\displaystyle \int \csc^{2}u \cdot du =$ $-\cot u + \text{C}$

Integral do seno ao cubo ou seno cúbico

$\displaystyle \int \sin^{3}u \cdot du =$ $- \cfrac{1}{3} \cdot (2 + \sin^{2} u) \cdot \cos u + \text{C}$

Integral de cosseno ao cubo ou cosseno cúbico

$\displaystyle \int \cos^{3}u \cdot du =$ $\cfrac{1}{3} \cdot (2 + \cos^{2} u) \cdot \sin u + \text{C}$

Integral da tangente ao cubo ou tangente cúbica

$\displaystyle \int \tan^{3}u \cdot du =$ $\cfrac{1}{2} \cdot \tan^{2}u + \ln |\cos u| + \text{C}$

Integral de cotangente ao cubo ou cotangente cúbica

$\displaystyle \int \cot^{3}u \cdot du =$ $- \cfrac{1}{2}\cdot \cot^{2}u - \ln |\sin u| + \text{C}$

Integral da secante ao cubo ou secante cúbica

$\displaystyle \int \sec^{3}u \cdot du =$ $\cfrac{1}{2} \cdot \sec u \cdot \tan u + \cfrac{1}{2} \cdot \ln |\sec u + \tan u| + \text{C}$

Integral de cossecante ao cubo ou cossecante cúbica

$\displaystyle \int \csc^{3}u \cdot du =$ $- \cfrac{1}{2} \cdot \csc u \cdot \cot u + \cfrac{1}{2} \cdot \ln |\csc u - \cot u| + \text{C}$

$\displaystyle \int \sin au \cdot \sin bu \cdot du =$ $\cfrac{\sin(a - b)\cdot u}{2 \cdot (a - b)} - \cfrac{\sin(a + b) \cdot u}{2 \cdot (a+b)}+ \text{C}$
$\displaystyle \int \cos au \cdot \cos bu \cdot du =$ $\cfrac{\sin(a - b) \cdot u}{2 \cdot (a - b)} + \cfrac{\sin(a + b) \cdot u}{2 \cdot (a+b)} + \text{C}$
$\displaystyle \int \sin au \cdot \cos bu \cdot du =$ $- \cfrac{\cos(a - b) \cdot u}{2 \cdot (a - b)} - \cfrac{\cos(a + b) \cdot u}{2 \cdot (a + b)} + \text{C}$
$\displaystyle \int u \cdot \sin u \cdot du =$ $\sin u - u \cdot \cos u + \text{C}$
$\displaystyle \int u \cdot \cos u \cdot du =$ $\cos u + u \cdot \sin u + \text{C}$

Fórmulas integrais trigonométricas de redução

$\displaystyle \int \sin^{n}u \cdot du =$ $- \cfrac{1}{n} \cdot \sin^{n - 1} u \cdot \cos u +$ $\displaystyle \cfrac{n-1}{n} \cdot \int \sin^{n-2}u \cdot du + \text{C}$
$\displaystyle \int \cos^{n}u \cdot du =$ $\cfrac{1}{n} \cdot \cos^{n-1} u \cdot \sin u +$ $\displaystyle \cfrac{n-1}{n} \cdot \int \cos^{n-2}u \cdot du + \text{C}$
$\displaystyle \int \tan^{n}u \cdot du =$ $\displaystyle \cfrac{1}{1-n} \cdot \tan^{n - 1}u -$ $\int \tan^{n - 2} u \cdot du + \text{C}$
$\displaystyle \int \cot^{n}u \cdot du =$ $\displaystyle - \cfrac{1}{n - 1} \cdot \cos^{n - 1}u -$ $\displaystyle \int \cot^{n-2}u \cdot du + \text{C}$
$\displaystyle \int \sec^{n}u \cdot du =$ $\displaystyle \cfrac{1}{n-1} \cdot \tan u \cdot \sec^{n - 2}u +$ $\displaystyle \cfrac{n-2}{n-1} \cdot \int \sec^{n-2}u \cdot du + \text{C}$
$\displaystyle \int \csc^{n}u \cdot du =$ $\displaystyle - \cfrac{1}{n-1} \cdot \cot u \cdot \csc^{n - 2}u +$ $\displaystyle \cfrac{n-2}{n-1} \cdot \int \csc^{n - 2}u \cdot du + \text{C}$
$\displaystyle \int u^{n} \cdot \sin u \cdot du =$ $\displaystyle - u^{n} \cdot \cos u + n \cdot \int u^{n - 1} \cdot \cos u \cdot du + \text{C}$
$\displaystyle \int u^{n} \cdot \cos u \cdot du =$ $\displaystyle u^{n} \cdot \sin u - n \cdot \int u^{n - 1} \cdot \sin u \cdot du + \text{C}$
$\displaystyle \int \sin^{n}u \cdot \cos^{m}u \cdot du =$ $\displaystyle - \cfrac{\sin^{n - 1}u \cdot \cos^{m + 1} u}{n + m} + \cfrac{n - 1}{n + m} \cdot \int \sin^{n-2}u \cdot \cos^{m}u \cdot du + \text{C} =$ $\displaystyle \cfrac{\sin^{n + 1}u \cdot \cos^{m - 1} u}{n + m} + \cfrac{m-1}{n+m} \cdot \int \sin^{n}u \cdot \cos^{m-2}u \cdot du + \text{C}$

Fórmulas integrais trigonométricas inversas

$\displaystyle \int \sin^{-1}u \cdot du =$ $u \cdot \sin^{-1}u + \sqrt{1 - u^{2}} + \text{C}$
$\displaystyle \int \cos^{-1}u \cdot du =$ $u \cdot \cos^{-1}u - \sqrt{1 - u^{2}} + \text{C}$
$\displaystyle \int \tan^{-1}u \cdot du =$ $u \cdot \tan^{-1}u - \cfrac{1}{2} \cdot \ln \big ( 1+u^{2} \big ) + \text{C}$
$\displaystyle \int u \cdot \sin^{-1}u \cdot du =$ $\cfrac{2 \cdot u^{2} - 1}{4} \cdot \sin^{-1} u +$ $\cfrac{u \cdot \sqrt{1 - u^{2}}}{4} + \text{C}$
$\displaystyle \int u \cdot \cos^{-1}u \cdot du =$ $\cfrac{2 \cdot u^{2} - 1}{4} \cdot \cos^{-1} u - \cfrac{ u \cdot \sqrt{1-u^{2}}}{4} + \text{C}$
$\displaystyle \int u \cdot \tan^{-1}u \cdot du =$ $\cfrac{u^{2} + 1}{4} \cdot \tan^{-1}u - \cfrac{u}{2} + \text{C}$
$\displaystyle \int u^{n} \cdot \sin^{-1} u \cdot du =$ $\displaystyle \cfrac{1}{n + 1} \cdot \Bigg [ u^{n+1} \cdot \sin^{-1}u - \int \cfrac{u^{n + 1} \cdot du}{\sqrt{1 - u^{2}}} \Bigg ] + \text{C},$ $\quad n \neq -1$
$\displaystyle \int \ u^{n} \cdot \cos^{-1}u \cdot du =$ $\displaystyle \cfrac{1}{n + 1} \cdot \Bigg [ u^{n + 1} \cdot \cos^{-1}u + \int \cfrac{u^{n + 1} \cdot du}{ \sqrt{1 - u^{2}}} \Bigg ] + \text{C},$ $\quad n \neq -1$
$\displaystyle \int u^{n} \cdot \tan^{-1}u \cdot du =$ $\displaystyle \cfrac{1}{n + 1} \cdot \Bigg [ u^{n + 1} \cdot \tan^{-1}u - \int \cfrac{u^{n + 1} \cdot du}{1 + u^{2}} \Bigg ] + \text{C},$ $\quad n \neq -1$

Substituições importantes das integrais

Se tem que $u = a \cdot x + b$
$\displaystyle \int F(a \cdot x + b) \cdot dx =$ $\displaystyle \cfrac{1}{a} \cdot \int F(u) \cdot du + \text{C}$
Se tem que $u = \sqrt{a \cdot x + b}$
$\displaystyle \int F \big ( \sqrt{a \cdot x + b} \big ) \cdot dx =$ $\displaystyle \cfrac{2}{a} \cdot \int u \cdot F(u) \cdot du + \text{C}$
Se tem que $u = (a \cdot x + b)^{1/n}$
$\displaystyle \int F \big ( (a \cdot x + b)^{1/n} \big ) \cdot dx =$ $\displaystyle \cfrac{n}{a} \cdot \int u^{n-1} \cdot F(u) \cdot du + \text{C}$
Se tem que $u = a \cdot \sin u$
$\displaystyle \int F \big ( \sqrt{a^{2} - x^{2}} \big ) \cdot dx =$ $\displaystyle a \cdot \int F(a \cdot \cos u) \cdot \cos u \cdot du + \text{C}$
Se tem que $u = a \cdot \tan u$
$\displaystyle \int F \big ( \sqrt{x^{2} + a^{2}} \big ) \cdot dx =$ $\displaystyle a \cdot \int F(a \cdot \sec u) \cdot \sec^{2} u \cdot du + \text{C}$
Se tem que $u = a \cdot \sec u$
$\displaystyle \int \ F \big ( \sqrt{x^{2} - a^{2}} \big ) \cdot dx =$ $\displaystyle a \cdot \int \ F(a \cdot \tan u) \cdot \sec u \cdot \tan u \cdot du + \text{C}$
Se tem que $u = e^{a \cdot x}$
$\displaystyle \int F(e^{a\cdot x}) \cdot dx =$ $\displaystyle \cfrac{1}{a} \cdot \int \cfrac{F(u)}{u} \cdot du + \text{C}$
Se tem que $u = \ln x$
$\displaystyle \int F(\ln x) \cdot dx =$ $\displaystyle \cfrac{1}{a} \cdot \int F(u) \cdot e^{u} \cdot du + \text{C}$
Se tem que $u = \sin^{-1} \cfrac{x}{a}$
$\displaystyle \int F \bigg ( \sin^{-1} \cfrac{x}{a} \bigg ) \cdot dx =$ $\displaystyle a \cdot \int F(u) \cdot \cos u \cdot du + \text{C}$

Obrigado por estar conosco neste momento : )