Let G Be a Continuous Function Using the Substitution U 2x 1 the Integral
Learning Objectives
- 5.5.1 Use substitution to evaluate indefinite integrals.
- 5.5.2 Use substitution to evaluate definite integrals.
The Fundamental Theorem of Calculus gave us a method to evaluate integrals without using Riemann sums. The drawback of this method, though, is that we must be able to find an antiderivative, and this is not always easy. In this section we examine a technique, called integration by substitution, to help us find antiderivatives. Specifically, this method helps us find antiderivatives when the integrand is the result of a chain-rule derivative.
At first, the approach to the substitution procedure may not appear very obvious. However, it is primarily a visual task—that is, the integrand shows you what to do; it is a matter of recognizing the form of the function. So, what are we supposed to see? We are looking for an integrand of the form For example, in the integral we have and Then,
and we see that our integrand is in the correct form.
The method is called substitution because we substitute part of the integrand with the variable u and part of the integrand with du. It is also referred to as change of variables because we are changing variables to obtain an expression that is easier to work with for applying the integration rules.
Theorem 5.7
Substitution with Indefinite Integrals
Let where is continuous over an interval, let be continuous over the corresponding range of g, and let be an antiderivative of Then,
(5.19)
Proof
Let f, g, u, and F be as specified in the theorem. Then
Integrating both sides with respect to x, we see that
If we now substitute and we get
□
Returning to the problem we looked at originally, we let and then Rewrite the integral in terms of u:
Using the power rule for integrals, we have
Substitute the original expression for x back into the solution:
We can generalize the procedure in the following Problem-Solving Strategy.
Problem-Solving Strategy
Problem-Solving Strategy: Integration by Substitution
- Look carefully at the integrand and select an expression within the integrand to set equal to u. Let's select such that is also part of the integrand.
- Substitute and into the integral.
- We should now be able to evaluate the integral with respect to u. If the integral can't be evaluated we need to go back and select a different expression to use as u.
- Evaluate the integral in terms of u.
- Write the result in terms of x and the expression
Example 5.30
Using Substitution to Find an Antiderivative
Use substitution to find the antiderivative
Analysis
We can check our answer by taking the derivative of the result of integration. We should obtain the integrand. Picking a value for C of 1, we let We have
so
This is exactly the expression we started with inside the integrand.
Checkpoint 5.25
Use substitution to find the antiderivative
Sometimes we need to adjust the constants in our integral if they don't match up exactly with the expressions we are substituting.
Example 5.31
Using Substitution with Alteration
Use substitution to find
Checkpoint 5.26
Use substitution to find
Example 5.32
Using Substitution with Integrals of Trigonometric Functions
Use substitution to evaluate the integral
Checkpoint 5.27
Use substitution to evaluate the integral
Sometimes we need to manipulate an integral in ways that are more complicated than just multiplying or dividing by a constant. We need to eliminate all the expressions within the integrand that are in terms of the original variable. When we are done, u should be the only variable in the integrand. In some cases, this means solving for the original variable in terms of u. This technique should become clear in the next example.
Example 5.33
Finding an Antiderivative Using u-Substitution
Use substitution to find the antiderivative
Checkpoint 5.28
Use substitution to evaluate the indefinite integral
Substitution for Definite Integrals
Substitution can be used with definite integrals, too. However, using substitution to evaluate a definite integral requires a change to the limits of integration. If we change variables in the integrand, the limits of integration change as well.
Theorem 5.8
Substitution with Definite Integrals
Let and let be continuous over an interval and let f be continuous over the range of Then,
Although we will not formally prove this theorem, we justify it with some calculations here. From the substitution rule for indefinite integrals, if is an antiderivative of we have
Then
(5.20)
and we have the desired result.
Example 5.34
Using Substitution to Evaluate a Definite Integral
Use substitution to evaluate
Checkpoint 5.29
Use substitution to evaluate the definite integral
Example 5.35
Using Substitution with an Exponential Function
Use substitution to evaluate
Checkpoint 5.30
Use substitution to evaluate
Substitution may be only one of the techniques needed to evaluate a definite integral. All of the properties and rules of integration apply independently, and trigonometric functions may need to be rewritten using a trigonometric identity before we can apply substitution. Also, we have the option of replacing the original expression for u after we find the antiderivative, which means that we do not have to change the limits of integration. These two approaches are shown in Example 5.36.
Example 5.36
Using Substitution to Evaluate a Trigonometric Integral
Use substitution to evaluate
Section 5.5 Exercises
254 .
Why is u-substitution referred to as change of variable?
255.
2. If when reversing the chain rule, should you take or
In the following exercises, verify each identity using differentiation. Then, using the indicated u-substitution, identify f such that the integral takes the form
256 .
257.
For
258 .
259.
260 .
In the following exercises, find the antiderivative using the indicated substitution.
261.
262 .
263.
264 .
265.
266 .
267.
268 .
269.
270 .
In the following exercises, use a suitable change of variables to determine the indefinite integral.
271.
272 .
273.
274 .
275.
276 .
277.
278 .
279.
280 .
281.
282 .
283.
284 .
285.
286 .
287.
In the following exercises, use a calculator to estimate the area under the curve using left Riemann sums with 50 terms, then use substitution to solve for the exact answer.
288 .
[T] over
289.
[T] over
290 .
[T] over
291.
[T] over
In the following exercises, use a change of variables to evaluate the definite integral.
292 .
293.
294 .
295.
296 .
297.
In the following exercises, evaluate the indefinite integral with constant using u-substitution. Then, graph the function and the antiderivative over the indicated interval. If possible, estimate a value of C that would need to be added to the antiderivative to make it equal to the definite integral with a the left endpoint of the given interval.
298 .
[T] over
299.
[T] on
300 .
[T] over
301.
[T] over
302 .
[T] over
303.
[T] over
304 .
If in what can you say about the value of the integral?
305.
Is the substitution in the definite integral okay? If not, why not?
In the following exercises, use a change of variables to show that each definite integral is equal to zero.
306 .
307.
308 .
309.
310 .
311.
312 .
313.
Show that the average value of over an interval is the same as the average value of over the interval for
314 .
Find the area under the graph of between and where and is fixed, and evaluate the limit as
315.
Find the area under the graph of between and where and is fixed. Evaluate the limit as
316 .
The area of a semicircle of radius 1 can be expressed as Use the substitution to express the area of a semicircle as the integral of a trigonometric function. You do not need to compute the integral.
317.
The area of the top half of an ellipse with a major axis that is the x-axis from to and with a minor axis that is the y-axis from to can be written as Use the substitution to express this area in terms of an integral of a trigonometric function. You do not need to compute the integral.
318 .
[T] The following graph is of a function of the form Estimate the coefficients a and b, and the frequency parameters n and m. Use these estimates to approximate
319.
[T] The following graph is of a function of the form Estimate the coefficients a and b and the frequency parameters n and m. Use these estimates to approximate
mckenziefacticked.blogspot.com
Source: https://openstax.org/books/calculus-volume-1/pages/5-5-substitution
0 Response to "Let G Be a Continuous Function Using the Substitution U 2x 1 the Integral"
Post a Comment