Integration by trigonometric substitution Calculator & Solver

1

Solved example of integration by trigonometric substitution

$\int\sqrt{x^2+4}dx$

2

We can solve the integral $\int\sqrt{x^2+4}dx$ by applying integration method of trigonometric substitution using the substitution

$x=2\tan\left(\theta \right)$

Differentiate both sides of the equation $x=2\tan\left(\theta \right)$

$dx=\frac{d}{d\theta}\left(2\tan\left(\theta \right)\right)$

Find the derivative

$\frac{d}{d\theta}\left(2\tan\left(\theta \right)\right)$

The derivative of a function multiplied by a constant ($2$) is equal to the constant times the derivative of the function

$2\frac{d}{d\theta}\left(\tan\left(\theta \right)\right)$

The derivative of the tangent of a function is equal to secant squared of that function times the derivative of that function, in other words, if ${f(x) = tan(x)}$, then ${f'(x) = sec^2(x)\cdot D_x(x)}$

$2\sec\left(\theta \right)^2\frac{d}{d\theta}\left(\theta \right)$

The derivative of the linear function is equal to $1$

$2\sec\left(\theta \right)^2$

3

Now, in order to rewrite $d\theta$ in terms of $dx$, we need to find the derivative of $x$. We need to calculate $dx$, we can do that by deriving the equation above

$dx=2\sec\left(\theta \right)^2d\theta$

4

Substituting in the original integral, we get

$\int2\sqrt{4\tan\left(\theta \right)^2+4}\sec\left(\theta \right)^2d\theta$

5

Factor by the greatest common divisor $4$

$\int2\sqrt{4\left(\tan\left(\theta \right)^2+1\right)}\sec\left(\theta \right)^2d\theta$

$\int2\sqrt{2^2\tan\left(\theta \right)^2+4}\sec\left(\theta \right)^2d\theta$

Calculate the power $2^2$

$\int2\sqrt{4\tan\left(\theta \right)^2+4}\sec\left(\theta \right)^2d\theta$

$\int2\sqrt{4}\sqrt{\tan\left(\theta \right)^2+1}\sec\left(\theta \right)^2d\theta$

Calculate the power $\sqrt{4}$

$\int2\cdot 2\sqrt{\tan\left(\theta \right)^2+1}\sec\left(\theta \right)^2d\theta$

Multiply $2$ times $2$

$\int4\sqrt{\tan\left(\theta \right)^2+1}\sec\left(\theta \right)^2d\theta$

6

The power of a product is equal to the product of it's factors raised to the same power

$\int4\sqrt{\tan\left(\theta \right)^2+1}\sec\left(\theta \right)^2d\theta$

7

Applying the trigonometric identity: $\tan(x)^2+1=\sec(x)^2$

$\int4\sec\left(\theta \right)\sec\left(\theta \right)^2d\theta$

8

The integral of a constant by a function is equal to the constant multiplied by the integral of the function

$4\int\sec\left(\theta \right)\sec\left(\theta \right)^2d\theta$

9

When multiplying exponents with same base you can add the exponents: $\sec\left(\theta \right)\sec\left(\theta \right)^2$

$4\int\sec\left(\theta \right)^{3}d\theta$

$4\int\sec\left(\theta \right)^2\sec\left(\theta \right)^{\left(3-2\right)}d\theta$

Subtract the values $3$ and $-2$

$4\int\sec\left(\theta \right)^2\sec\left(\theta \right)^{1}d\theta$

Any expression to the power of $1$ is equal to that same expression

$4\int\sec\left(\theta \right)^2\sec\left(\theta \right)d\theta$

10

Rewrite $\sec\left(\theta \right)^{3}$ as the product of two secants

$4\int\sec\left(\theta \right)^2\sec\left(\theta \right)d\theta$

11

We can solve the integral $\int\sec\left(\theta \right)^2\sec\left(\theta \right)d\theta$ by applying integration by parts method to calculate the integral of the product of two functions, using the following formula

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

Taking the derivative of secant function: $\frac{d}{dx}\left(\sec(x)\right)=\sec(x)\cdot\tan(x)\cdot D_x(x)$

$\sec\left(\theta \right)\tan\left(\theta \right)$

12

First, identify $u$ and calculate $du$

$\begin{matrix}\displaystyle{u=\sec\left(\theta \right)}\\ \displaystyle{du=\sec\left(\theta \right)\tan\left(\theta \right)d\theta}\end{matrix}$

13

Now, identify $dv$ and calculate $v$

$\begin{matrix}\displaystyle{dv=\sec\left(\theta \right)^2d\theta}\\ \displaystyle{\int dv=\int \sec\left(\theta \right)^2d\theta}\end{matrix}$

14

Solve the integral

$v=\int\sec\left(\theta \right)^2d\theta$

15

The integral of $\sec(x)^2$ is $\tan(x)$

$\tan\left(\theta \right)$

When multiplying two powers that have the same base ($\tan\left(\theta \right)$), you can add the exponents

$4\left(\tan\left(\theta \right)\sec\left(\theta \right)-\int\tan\left(\theta \right)^2\sec\left(\theta \right)d\theta\right)$

16

Now replace the values of $u$, $du$ and $v$ in the last formula

$4\left(\tan\left(\theta \right)\sec\left(\theta \right)-\int\tan\left(\theta \right)^2\sec\left(\theta \right)d\theta\right)$

$4\tan\left(\theta \right)\sec\left(\theta \right)+4\left(-1\right)\int\tan\left(\theta \right)^2\sec\left(\theta \right)d\theta$

Multiply $4$ times $-1$

$4\tan\left(\theta \right)\sec\left(\theta \right)-4\int\tan\left(\theta \right)^2\sec\left(\theta \right)d\theta$

17

Solve the product $4\left(\tan\left(\theta \right)\sec\left(\theta \right)-\int\tan\left(\theta \right)^2\sec\left(\theta \right)d\theta\right)$

$4\tan\left(\theta \right)\sec\left(\theta \right)-4\int\tan\left(\theta \right)^2\sec\left(\theta \right)d\theta$

Apply the formula: $\int\sec\left(x\right)\tan\left(x\right)^2dx$$=\int\sec\left(x\right)^3dx-\int\sec\left(x\right)dx$, where $x=\theta $

$-4\int\sec\left(\theta \right)^3d\theta+4\int\sec\left(\theta \right)d\theta$

The integral of the secant function is given by the following formula, $\displaystyle\int\sec(x)dx=\ln\left|\sec(x)+\tan(x)\right|$

$-4\int\sec\left(\theta \right)^3d\theta+4\ln\left(\sec\left(\theta \right)+\tan\left(\theta \right)\right)$

Rewrite $\sec\left(\theta \right)^3$ as the product of two secants

$-4\int\sec\left(\theta \right)^2\sec\left(\theta \right)d\theta+4\ln\left(\sec\left(\theta \right)+\tan\left(\theta \right)\right)$

We can solve the integral $\int\sec\left(\theta \right)^2\sec\left(\theta \right)d\theta$ by applying integration by parts method to calculate the integral of the product of two functions, using the following formula

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

First, identify $u$ and calculate $du$

$\begin{matrix}\displaystyle{u=\sec\left(\theta \right)}\\ \displaystyle{du=\sec\left(\theta \right)\tan\left(\theta \right)d\theta}\end{matrix}$

Now, identify $dv$ and calculate $v$

$\begin{matrix}\displaystyle{dv=\sec\left(\theta \right)^2d\theta}\\ \displaystyle{\int dv=\int \sec\left(\theta \right)^2d\theta}\end{matrix}$

Solve the integral

$v=\int\sec\left(\theta \right)^2d\theta$

The integral of $\sec(x)^2$ is $\tan(x)$

$\tan\left(\theta \right)$

Now replace the values of $u$, $du$ and $v$ in the last formula

$-4\left(\tan\left(\theta \right)\sec\left(\theta \right)-\int\tan\left(\theta \right)^2\sec\left(\theta \right)d\theta\right)+4\ln\left(\sec\left(\theta \right)+\tan\left(\theta \right)\right)$

Solve the product $-4\left(\tan\left(\theta \right)\sec\left(\theta \right)-\int\tan\left(\theta \right)^2\sec\left(\theta \right)d\theta\right)$

$-4\tan\left(\theta \right)\sec\left(\theta \right)-4\left(-1\right)\int\tan\left(\theta \right)^2\sec\left(\theta \right)d\theta+4\ln\left(\sec\left(\theta \right)+\tan\left(\theta \right)\right)$

Multiply $-4$ times $-1$

$-4\tan\left(\theta \right)\sec\left(\theta \right)+4\int\tan\left(\theta \right)^2\sec\left(\theta \right)d\theta+4\ln\left(\sec\left(\theta \right)+\tan\left(\theta \right)\right)$

Apply the formula: $\int\sec\left(x\right)\tan\left(x\right)^2dx$$=\int\sec\left(x\right)^3dx-\int\sec\left(x\right)dx$, where $x=\theta $

$-4\tan\left(\theta \right)\sec\left(\theta \right)+4\int\sec\left(\theta \right)^3d\theta-4\int\sec\left(\theta \right)d\theta+4\ln\left(\sec\left(\theta \right)+\tan\left(\theta \right)\right)$

The integral of the secant function is given by the following formula, $\displaystyle\int\sec(x)dx=\ln\left|\sec(x)+\tan(x)\right|$

$-4\tan\left(\theta \right)\sec\left(\theta \right)+4\int\sec\left(\theta \right)^3d\theta-4\ln\left(\sec\left(\theta \right)+\tan\left(\theta \right)\right)+4\ln\left(\sec\left(\theta \right)+\tan\left(\theta \right)\right)$

Cancel like terms $-4\ln\left(\sec\left(\theta \right)+\tan\left(\theta \right)\right)$ and $4\ln\left(\sec\left(\theta \right)+\tan\left(\theta \right)\right)$

$-4\tan\left(\theta \right)\sec\left(\theta \right)+4\int\sec\left(\theta \right)^3d\theta$

Simplify the integral $\int\sec\left(\theta \right)^3d\theta$ applying the reduction formula, $\displaystyle\int\sec(x)^{n}dx=\frac{\sin(x)\sec(x)^{n-1}}{n-1}+\frac{n-2}{n-1}\int\sec(x)^{n-2}dx$

$-4\tan\left(\theta \right)\sec\left(\theta \right)+4\left(\frac{\sin\left(\theta \right)\sec\left(\theta \right)^{2}}{2}+\frac{1}{2}\int\sec\left(\theta \right)d\theta\right)$

Solve the product $4\left(\frac{\sin\left(\theta \right)\sec\left(\theta \right)^{2}}{2}+\frac{1}{2}\int\sec\left(\theta \right)d\theta\right)$

$-4\tan\left(\theta \right)\sec\left(\theta \right)+2\sin\left(\theta \right)\sec\left(\theta \right)^{2}+2\int\sec\left(\theta \right)d\theta$

Simplifying

$-2\tan\left(\theta \right)\sec\left(\theta \right)+2\int\sec\left(\theta \right)d\theta$

The integral of the secant function is given by the following formula, $\displaystyle\int\sec(x)dx=\ln\left|\sec(x)+\tan(x)\right|$

$-2\tan\left(\theta \right)\sec\left(\theta \right)+2\ln\left(\sec\left(\theta \right)+\tan\left(\theta \right)\right)$

Express the variable $\theta$ in terms of the original variable $x$

$-2\left(\frac{x}{2}\right)\left(\frac{\sqrt{x^2+4}}{2}\right)+2\ln\left(\frac{\sqrt{x^2+4}}{2}+\frac{x}{2}\right)$

Multiplying the fraction by $-2$

$\frac{-2x}{2}\frac{\sqrt{x^2+4}}{2}+2\ln\left(\frac{\sqrt{x^2+4}}{2}+\frac{x}{2}\right)$

Take $\frac{-2}{2}$ out of the fraction

$-\frac{1}{2}x\sqrt{x^2+4}+2\ln\left(\frac{\sqrt{x^2+4}}{2}+\frac{x}{2}\right)$

Add fraction's numerators with common denominators: $\frac{\sqrt{x^2+4}}{2}$ and $\frac{x}{2}$

$-\frac{1}{2}x\sqrt{x^2+4}+2\ln\left(\frac{\sqrt{x^2+4}+x}{2}\right)$

18

The integral $-4\int\tan\left(\theta \right)^2\sec\left(\theta \right)d\theta$ results in: $-\frac{1}{2}x\sqrt{x^2+4}+2\ln\left(\frac{\sqrt{x^2+4}+x}{2}\right)$

$-\frac{1}{2}x\sqrt{x^2+4}+2\ln\left(\frac{\sqrt{x^2+4}+x}{2}\right)$

19

Gather the results of all integrals

$4\tan\left(\theta \right)\sec\left(\theta \right)+2\ln\left(\frac{\sqrt{x^2+4}+x}{2}\right)-\frac{1}{2}x\sqrt{x^2+4}$

20

Express the variable $\theta$ in terms of the original variable $x$

$4\left(\frac{x}{2}\right)\left(\frac{\sqrt{x^2+4}}{2}\right)+2\ln\left(\frac{\sqrt{x^2+4}+x}{2}\right)-\frac{1}{2}x\sqrt{x^2+4}$

21

Multiplying the fraction by $4$

$\frac{4x}{2}\frac{\sqrt{x^2+4}}{2}+2\ln\left(\frac{\sqrt{x^2+4}+x}{2}\right)-\frac{1}{2}x\sqrt{x^2+4}$

22

Take $\frac{4}{2}$ out of the fraction

$x\sqrt{x^2+4}+2\ln\left(\frac{\sqrt{x^2+4}+x}{2}\right)-\frac{1}{2}x\sqrt{x^2+4}$

23

Adding $-\frac{1}{2}\sqrt{x^2+4}x$ and $\sqrt{x^2+4}x$

$2\ln\left(\frac{\sqrt{x^2+4}+x}{2}\right)+\frac{1}{2}x\sqrt{x^2+4}$

24

As the integral that we are solving is an indefinite integral, when we finish integrating we must add the constant of integration $C$

$2\ln\left(\frac{\sqrt{x^2+4}+x}{2}\right)+\frac{1}{2}x\sqrt{x^2+4}+C_0$

25

Simplify the expression by applying logarithm properties

$\frac{1}{2}x\sqrt{x^2+4}+2\ln\left(\sqrt{x^2+4}+x\right)+C_1$

Integration by trigonometric substitution Calculator

Get detailed solutions to your math problems with our Integration by trigonometric substitution step-by-step calculator. Practice your math skills and learn step by step with our math solver. Check out all of our online calculators here!

Example

Solved Problems

Difficult Problems

Final Answer

Struggling with math?

Integration by trigonometric substitution Calculator

Get detailed solutions to your math problems with our Integration by trigonometric substitution step-by-step calculator. Practice your math skills and learn step by step with our math solver. Check out all of our online calculators here!

Example

Solved Problems

Difficult Problems

Final Answer

Struggling with math?

Related Calculators