13.08 Integration using substitution
We used the chain rule to differentiate composite functions. Let's go back for a moment to differentiating a function like $y=\left(x^2+1\right)^4$y=(x2+1)4. Since it's a function of the form $y=f\left(x\right)^n$y=f(x)n, we can use the chain rule to differentiate. Doing this, we get:
| $y$y | $=$= | $\left(x^2+1\right)^4$(x2+1)4 | The function is of the form $y=f\left(x\right)^n$y=f(x)n | |
| $\frac{dy}{dx}$dydx | $=$= | $4\left(x^2+1\right)^3\times2x$4(x2+1)3×2x | The derivative is of the form $\frac{dy}{dx}=n\times f\left(x\right)^{n-1}\times f'\left(x\right)$dydx=n×f(x)n−1×f′(x) | |
| $\frac{dy}{dx}$dydx | $=$= | $8x\left(x^2+1\right)^3$8x(x2+1)3 |
Integration by substitution is a method we can use to reverse this differentiation method. Notice that $\frac{dy}{dx}$dydx is of the form $f'\left(x\right)\times f\left(x\right)^n$f′(x)×f(x)n.
Integration by substitution will help us integrate functions like this.
To use integration by substitution, we look for an integral which looks like:
$\int k\times f'\left(x\right)\times f\left(x\right)\ dx$∫k×f′(x)×f(x) dx
It contains an expression that is raised to a power and the derivative of that expression.
Indefinite integrals using substitution
When we are given a substitution to use to determine an integral, it is useful to follow the following steps to arrive at a solution:
- Rewrite the integral in the form $\int k\times f'\left(x\right)\times f\left(x\right)\ dx$∫k×f′(x)×f(x) dx
- Using $\frac{du}{dx}$dudx, determine a relationship between $dx$dx and $du$du
- Rewrite the integral in terms of $u$u and $du$du by making appropriate substitutions
- Solve the new integral in terms of $u$u
- Make a substitution for $u$u to rewrite the solution to the integral in terms of $x$x
Worked example
Example 1
Evaluate $\int10x\left(2+x^2\right)^4dx$∫10x(2+x2)4dx using the substitution $u=2+x^2$u=2+x2.
Think: We are given the substitution $u=f\left(x\right)=2+x^2$u=f(x)=2+x2. The first step will be to find $f'\left(x\right)$f′(x) so that we can rewrite the integral in the form:
$\int k\times f'\left(x\right)\times f\left(x\right)\ dx$∫k×f′(x)×f(x) dx
Do: Taking the derivative of $f\left(x\right)$f(x) gives:
| $f'\left(x\right)$f′(x) | $=$= | $2x$2x |
We have $f\left(x\right)=2+x^2$f(x)=2+x2 and $f'\left(x\right)=2x$f′(x)=2x. But we have a $10x$10x term in the original integral. Therefore:
| $k\times f'\left(x\right)$k×f′(x) | $=$= | $10x$10x |
| $k\times2x$k×2x | $=$= | $10x$10x |
| $k$k | $=$= | $5$5 |
Rewriting the integral in the form $\int k\times f'\left(x\right)\times f\left(x\right)\ dx$∫k×f′(x)×f(x) dx with $k=5$k=5:
| $\int10x\left(2+x^2\right)^4dx$∫10x(2+x2)4dx | $=$= | $\int5\times2x\left(2+x^2\right)^4dx$∫5×2x(2+x2)4dx |
The next step is to determine a relationship between $dx$dx and $du$du. We have:
| $f'\left(x\right)=\frac{du}{dx}$f′(x)=dudx | $=$= | $2x$2x |
Therefore:
| $du$du | $=$= | $2xdx$2xdx |
So $2xdx$2xdx can be replaced by $du$du and $u=2+x^2$u=2+x2. Rewriting the integral in terms of $u$u gives:
| $\int10x\left(2+x^2\right)^4dx$∫10x(2+x2)4dx | $=$= | $\int5u^4du$∫5u4du |
Evaluating this integral:
| $\int5u^4du$∫5u4du | $=$= | $\frac{5u^5}{5}+C$5u55+C |
| $\int5u^4du$∫5u4du | $=$= | $u^5+C$u5+C |
But $u=2+x^2$u=2+x2. Therefore, making a substitution for $u$u in terms of $x$x reveals the solution to the original integral:
| $\int10x\left(2+x^2\right)^4dx$∫10x(2+x2)4dx | $=$= | $\left(2+x^2\right)^5+C$(2+x2)5+C |
Practice questions
Question 1
We want to find $\int5\left(5x+4\right)^3dx$∫5(5x+4)3dx using the substitution $u=5x+4$u=5x+4.
Find $\frac{du}{dx}$dudx.
Which of the following is a correct expression relating $du$du and $dx$dx?
$du=\frac{dx}{5}$du=dx5
A$du=dx$du=dx
B$dx=\frac{du}{5}$dx=du5
CEvaluate the integral $\int5\left(5x+4\right)^3dx$∫5(5x+4)3dx by making the substitutions from previous parts. Use $C$C as the constant term, leave your answer in terms of $x$x.
Question 2
We want to find $\int3x^2\left(x^3+7\right)^4dx$∫3x2(x3+7)4dx using the substitution $u=x^3+7$u=x3+7.
Find $\frac{du}{dx}$dudx.
Which of the following is a correct expression relating $du$du and $dx$dx?
$dx=\frac{du}{3x^2}$dx=du3x2
A$du=\frac{dx}{3x^2}$du=dx3x2
B$du=dx$du=dx
CEvaluate the integral $\int3x^2\left(x^3+7\right)^4dx$∫3x2(x3+7)4dx by making the substitutions from previous parts. Use $C$C as the constant term, leave your answer in terms of $x$x.
Definite integrals using substitution
Definite integrals are approached in the same manner as indefinite integrals except they require the extra step of recalculation of the limits of the integral according to the substitution variable. This also means that a final substitution is not required as the integral is evaluated in terms of the equivalent substituted variable. We will revisit our example above with integral limits added to see the difference.
Worked examples
Example 2
Evaluate $\int_0^110x\left(2+x^2\right)^4dx$∫1010x(2+x2)4dx using the substitution $u=2+x^2$u=2+x2.
Think: We need to change the limits to $u$u values. Using $u=2+x^2$u=2+x2.
Do:
When $x=0$x=0, $u=2$u=2
When $x=1$x=1, $u=3$u=3
Using the newly calculated limits for $u$u and rewriting the integral in terms of $u$u with the substitutions determined in the worked example above gives:
| $\int_0^110x\left(2+x^2\right)^4dx$∫1010x(2+x2)4dx | $=$= | $\int_2^35u^4du$∫325u4du |
Evaluating $\int_2^35u^4du$∫325u4du:
| $\int_2^35u^4du$∫325u4du | $=$= | $\left[\frac{5u^5}{5}\right]_2^3$[5u55]32 |
| $\int_2^35u^4du$∫325u4du | $=$= | $\left[u^5\right]_2^3$[u5]32 |
| $\int_2^35u^4du$∫325u4du | $=$= | $3^5-2^5$35−25 |
| $\int_2^35u^4du$∫325u4du | $=$= | $243-32$243−32 |
| $\int_2^35u^4du$∫325u4du | $=$= | $211$211 |
Example 3
Evaluate $\int_1^6\frac{2}{\sqrt{x+3}}dx$∫612√x+3dx using the substitution $u=x+3$u=x+3.
Think: We start by calculating the new limit values for $u$u:
Do:
Step 1: Changing the limits to $u$u values. Using $u=x+3$u=x+3:
When $x=1$x=1, $u=4$u=4
When $x=6$x=6, $u=9$u=9
Step 2: We need to replace $dx$dx by creating a relationship between $dx$dx and $du$du. The derivative of $u=x+3$u=x+3 gives:
| $\frac{du}{dx}$dudx | $=$= | $1$1 |
Rearranging this, we get:
| $du$du | $=$= | $dx$dx |
So $dx$dx can be replaced with $du$du.
Step 3: We rewrite the integral in terms of $u$u:
| $\int_1^6\frac{2}{\sqrt{x+3}}dx$∫612√x+3dx | $=$= | $\int_4^9\frac{2}{\sqrt{u}}du$∫942√udu |
Step 4: We evaluate the new integral in terms of $u$u.
| $\int_4^9\frac{2}{\sqrt{u}}du$∫942√udu | $=$= | $\int_4^9\frac{2}{u^{\frac{1}{2}}}du$∫942u12du |
| $=$= | $\int_4^92u^{-\frac{1}{2}}du$∫942u−12du | |
| $=$= | $\left[\frac{2u^{\frac{1}{2}}}{\frac{1}{2}}\right]_4^9$[2u1212]94 | |
| $=$= | $\left[4u^{\frac{1}{2}}\right]_4^9$[4u12]94 | |
| $=$= | $4\times9^{\frac{1}{2}}-4\times4^{\frac{1}{2}}$4×912−4×412 | |
| $=$= | $4\times3-4\times2$4×3−4×2 | |
| $=$= | $4$4 |
Practice questions
Question 3
We want to find $\int_6^8\left(3x-15\right)^2dx$∫86(3x−15)2dx using the substitution $u=3x-15$u=3x−15.
Fill in the missing numbers.
When $x=6$x=6, $u=\editable{}$u=.
When $x=8$x=8, $u=\editable{}$u=.
Find $\frac{du}{dx}$dudx.
Which of the following is a correct expression relating $du$du and $dx$dx?
$dx=\frac{du}{3}$dx=du3
A$du=\frac{dx}{3}$du=dx3
B$dx=\frac{1}{du}$dx=1du
C$du=dx$du=dx
DEvaluate the integral $\int_6^8\left(3x-15\right)^2dx$∫86(3x−15)2dx by making the substitutions from previous parts.
Question 4
We want to find $\int_0^1\frac{-144x^3}{\left(2x^4-3\right)^3}dx$∫10−144x3(2x4−3)3dx using the substitution $u=2x^4-3$u=2x4−3.
Fill in the missing numbers.
When $x=0$x=0, $u=\editable{}$u=.
When $x=1$x=1, $u=\editable{}$u=.
Find $\frac{du}{dx}$dudx.
Which of the following is a correct expression relating $du$du and $dx$dx?
$du=\frac{dx}{8x^3}$du=dx8x3
A$du=dx$du=dx
B$dx=\frac{du}{8x^3}$dx=du8x3
C$dx=\frac{1}{du}$dx=1du
DEvaluate the integral $\int_0^1\frac{-144x^3}{\left(2x^4-3\right)^3}dx$∫10−144x3(2x4−3)3dx by making the substitutions in previous parts.
QUESTION 5
We want to find $\int_0^1\left(4x^3+5\right)\left(x^4+5x+2\right)^3dx$∫10(4x3+5)(x4+5x+2)3dx using the substitution $u=x^4+5x+2$u=x4+5x+2.
Fill in the missing numbers.
When $x=0$x=0, $u=\editable{}$u=.
When $x=1$x=1, $u=\editable{}$u=.
Find $\frac{du}{dx}$dudx.
Which of the following is a correct expression relating $du$du and $dx$dx?
$du=\left(4x^3+5\right)dx$du=(4x3+5)dx
A$du=dx$du=dx
B$dx=\frac{1}{du}$dx=1du
C$dx=\left(4x^3+5\right)du$dx=(4x3+5)du
DEvaluate the integral $\int_0^1\left(4x^3+5\right)\left(x^4+5x+2\right)^3dx$∫10(4x3+5)(x4+5x+2)3dx by making the substitutions in previous parts.