Difference between revisions of "Integration by Parts"

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==Exercises==
 
==Exercises==
 
Evaluate the following using integration by parts.
 
Evaluate the following using integration by parts.
{{question-answer|question=1. <math>\int -4\ln(x)dx</math>|answer={{noprint|<math>4x-4x\ln(x)+C</math>}}}}
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# <math>\int -4\ln(x)dx</math>
 
+
# <math>\int (38-7x)\cos(x)dx</math>
{{question-answer|question=2. <math>\int (38-7x)\cos(x)dx</math>|answer={{noprint|<math>(38-7x)\sin(x)-7\cos(x)+C</math>}}}}
+
# <math>\int\limits_0^\tfrac{\pi}{2} (-6x+45)\cos(x)dx</math>
 
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# <math>\int(5x+1)(x-6)^4 dx</math>
{{question-answer|question=3. <math>\int\limits_0^\tfrac{\pi}{2} (-6x+45)\cos(x)dx</math>|answer={{noprint|<math>51-3\pi</math>}}}}
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# <math>\int\limits_{-1}^1 (2x+8)^3(2-x)dx</math>
 
 
{{question-answer|question=4. <math>\int(5x+1)(x-6)^4 dx</math>|answer={{noprint|<math>\frac{(5x+1)(x-6)^5}{5}-\frac{(x-6)^6}{6}+C</math>}}}}
 
 
 
{{question-answer|question=5. <math>\int\limits_{-1}^1 (2x+8)^3(2-x)dx</math>|answer={{noprint|<math>1916.8</math>}}}}
 
{{noprint|[[Calculus/Integration_techniques/Integration_by_Parts/Solutions|Solutions]]}}
 
 
 
  
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==Exercise Solutions==
 +
# <math>4x-4x\ln(x)+C</math>
 +
# <math>(38-7x)\sin(x)-7\cos(x)+C</math>
 +
# <math>51-3\pi</math>
 +
# <math>\frac{(5x+1)(x-6)^5}{5}-\frac{(x-6)^6}{6}+C</math>
 +
# <math>1916.8</math>
  
 
==Resources==
 
==Resources==
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[https://youtu.be/CxV5HE6chSY Integration by Parts Example 4 ] by Krista King
 
[https://youtu.be/CxV5HE6chSY Integration by Parts Example 4 ] by Krista King
 +
 +
==Licensing==
 +
Content obtained and/or adapted from:
 +
* [https://en.wikibooks.org/wiki/Calculus/Integration_techniques/Integration_by_Parts Integration by Parts, Wikibooks] under a CC BY-SA license

Latest revision as of 15:29, 28 October 2021

Continuing on the path of reversing derivative rules in order to make them useful for integration, we reverse the product rule.

Integration by parts

If where and are functions of , then

Rearranging,

Therefore,

Therefore,

or

This is the integration by parts formula. It is very useful in many integrals involving products of functions, as well as others.

For instance, to treat

we choose and . With these choices, we have and , and we have

Note that the choice of and was critical. Had we chosen the reverse, so that and , the result would have been

The resulting integral is no easier to work with than the original; we might say that this application of integration by parts took us in the wrong direction.

So the choice is important. One general guideline to help us make that choice is, if possible, to choose to be the factor of the integrand which becomes simpler when we differentiate it. In the last example, we see that does not become simpler when we differentiate it: is no simpler than .

An important feature of the integration by parts method is that we often need to apply it more than once. For instance, to integrate

we start by choosing and to get

Note that we still have an integral to take care of, and we do this by applying integration by parts again, with and , which gives us

So, two applications of integration by parts were necessary, owing to the power of in the integrand.

Note that any power of x does become simpler when we differentiate it, so when we see an integral of the form

one of our first thoughts ought to be to consider using integration by parts with . Of course, in order for it to work, we need to be able to write down an antiderivative for .

Example

Use integration by parts to evaluate the integral

Solution: If we let and , then we have and . Using our rule for integration by parts gives

We do not seem to have made much progress.

But if we integrate by parts again with and and hence and , we obtain

We may solve this identity to find the anti-derivative of and obtain

With definite integral

For definite integrals the rule is essentially the same, as long as we keep the endpoints.

Integration by parts for definite integrals Suppose f and g are differentiable and their derivatives are continuous. Then

.

This can also be expressed in Leibniz notation.

More Examples

Examples Set 1: Integration by Parts

Exercises

Evaluate the following using integration by parts.

Exercise Solutions

Resources

Videos

Integration by Parts: The Basics by James Sousa

Integration by Parts (After Integration by Parts Basics) by James Sousa

Integration by Parts - Additional Examples by James Sousa

Integration by Parts: The Basics by James Sousa

Deriving the Integration by Parts Formula - Easy! by patrickJMT

Integration by Parts Made Easy! by patrickJMT

Integration by Parts - Indefinite Integral by patrickJMT

Integration By Parts - Using IBP's Twice by patrickJMT

Integration by Parts - A Loopy Example! by patrickJMT

Integration by Parts - Definite Integral by patrickJMT

How does integration by parts work? by Krista King

Integration by Parts by Krista King

Integration by Parts Example 2 by Krista King

Integration by Parts Example 3 by Krista King

Integration by Parts Example 4 by Krista King

Licensing

Content obtained and/or adapted from: