Using substitution to combine integrals

In summary, using the given information, the two integrals can be combined by swapping the limits of the second integral, using a substitution, and then realizing that the dummy variable u can be replaced by any other variable, such as x. This results in the final integral: \int_{a}^{b}(-6)f(x)dx, which can then be combined with the first integral to obtain the solution.
  • #1
sara_87
763
0

Homework Statement



I want to combine the 2 integrals:

[tex]\int_{a}^{b}(x-3)f(x)dx+\int_{-b}^{-a}(x-3)f(x)dx
[/tex]

Homework Equations



given:
f(x) is an even function


The Attempt at a Solution



swap the limits in the second integral:

[tex]\int_{a}^{b}(x-3)f(x)dx-\int_{-a}^{-b}(x-3)f(x)dx[/tex]

use a substitution for the second integral:
let u=-x

since f(x) is even, we have f(-u)=f(u)
so:

[tex]\int_{a}^{b}(x-3)f(x)dx-\int_{a}^{b}(-u-3)f(u)(-du)[/tex]

[tex]\int_{a}^{b}(x-3)f(x)dx+\int_{a}^{b}(-u-3)f(u)(du)[/tex]


now I'm stuck. can i say this:
let u=x (sounds wrong since u=-x)
so:
[tex]\int_{a}^{b}(x-3)f(x)dx+\int_{a}^{b}(-x-3)f(x)(dx)[/tex]

which then can be easily combined with the first integral (now that the limits of integration are the same.

Any help will be very much appreciated. thank you
 
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  • #2
is the latex code shown ?
I typed it in but for some reason it is not shown on my computer. here it is anyway:

Homework Statement



I want to combine the 2 integrals:

\int_{a}^{b}(x-3)f(x)dx+\int_{-b}^{-a}(x-3)f(x)dx

Homework Equations



given:
f(x) is an even function


The Attempt at a Solution



swap the limits in the second integral:

\int_{a}^{b}(x-3)f(x)dx-\int_{-a}^{-b}(x-3)f(x)dx

use a substitution for the second integral:
let u=-x

since f(x) is even, we have f(-u)=f(u)
so:

\int_{a}^{b}(x-3)f(x)dx-\int_{a}^{b}(-u-3)f(u)(-du)

\int_{a}^{b}(x-3)f(x)dx+\int_{a}^{b}(-u-3)f(u)(du)

now I'm stuck. can i say this:
let u=x (sounds wrong since u=-x)
so:
\int_{a}^{b}(x-3)f(x)dx+\int_{a}^{b}(-x-3)f(x)(dx)

which then can be easily combined with the first integral (now that the limits of integration are the same.

Any help will be very much appreciated. thank you
 
  • #3
You already solved it! You just need to realize that [itex]u[/itex] is a dummy variable, as much so as [itex]x[/itex] in the first integral. You can therefore replace the [itex]u[/itex] by whatever you like, an [itex]x[/itex] for example..:wink:
 
  • #4
You almost did it.
But you should know that definite integrals are independent of the variables.

that is : [tex]\int_a^b f(u) du = \int_a^b f(x) dx[/tex]

So?
 
  • #5
I see :)
so, i can write this as
[tex]\int_{a}^{b}(-6)f(x)dx[tex]
 

1. What is the purpose of using substitution to combine integrals?

The purpose of using substitution to combine integrals is to simplify the integrand and make it easier to solve. By substituting a variable, we can transform the integral into a simpler form that is easier to integrate.

2. How do we know when to use substitution to combine integrals?

We can use substitution when the integrand contains a function and its derivative. This allows us to substitute the function with the variable, which will then simplify the integral.

3. What are the steps for using substitution to combine integrals?

The steps for using substitution to combine integrals are as follows:

1. Identify a function and its derivative in the integrand.

2. Substitute the function with a new variable.

3. Rewrite the integral in terms of the new variable.

4. Solve the integral with the new variable.

5. Substitute back in the original function to get the final answer.

4. Can substitution be used for all types of integrals?

No, substitution can only be used for certain types of integrals where the integrand contains a function and its derivative. For other types of integrals, we may need to use other techniques such as integration by parts.

5. How do we choose the appropriate substitution for a given integral?

To choose the appropriate substitution, we should look for a function and its derivative in the integrand. The function chosen should be simple and easy to integrate. We may also need to try different substitutions until we find one that simplifies the integral.

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