Introduction to Integration by Parts | Tabular Method for Integration by Parts |

Guidelines for Integration by Parts using LIATE | More Practice |

Integration by Parts Problems |

## Introduction to Integration by Parts

**Integration by Parts** is yet another integration trick that can be used when you have an integral that happens to be a **product** of algebraic, exponential, logarithm, or trigonometric functions.

The rule of thumb is to try to use **U-Substitution Integration**, but if that fails, try **Integration by Parts**. Typically, Integration by Parts is used when two functions are multiplied together, with one that can be easily integrated, and one that can be easily differentiated. It’s not always that easy though, as we’ll see below (but we’ll have some hints). And sometimes we have to use the procedure more than once! Here is the formal definition:

Here is an example:

**Guidelines for Integration by Parts using LIATE**

The most difficult thing about **Integration by Parts** is **1)** knowing if you should use it and **2)** deciding how to pick apart the integral. As with any form of integration, if you get to the point where you’re not going anywhere, it’s not the form of integration to use. And if it doesn’t work the first time, switch the integral parts and try again! Here are some hints that might help:

It makes sense that we want to look at the integral and determine what’s easier to integrate (which should be the $ dv$) and what’s easier to differentiate (to be the $ u$). Also, it’s best to let $ dv$ be the **most complicated part** of the integrand, and it should fit a basic integration rule. And it’s best to let $ u$ be the part of the integrand with a derivative simpler than $ u$ itself, if you can. And always remember that the $ dv$ part always includes the “$ dx$” of the original integral.

There’s a trick that uses an acronym to help. It has to do with which function should be the $ u$. It doesn’t work **100%**, but it’s sure helpful; the acronym is **LIATE**; use this order for picking $ u$. (**ILATE** works too, since you usually don’t have an inverse trig function and logarithmic function in same problem). Pick the $ u$ in this order:

**L**ogarithmic Functions, such as $ \log \left( x \right),\ln \left( x \right)$**I**nverse Trigonometric Functions, such as $ {{\sin }^{{-1}}}\left( x \right)$**A**lgebraic Functions, such as $ x,{{x}^{4}}$**T**rigonometric Functions, such as $ \sin \left( x \right)$**E**xponential Functions, such as $ {{2}^{x}},{{e}^{x}}$

## Integration by Parts Problems

Here are some problems; note that the answers are simplified in most cases.

Sometimes, we have to use Integration by Parts **twice**, as in the following example, where we have an $ {{x}^{2}}$ before the $ \sin x$. If we had an $ {{x}^{3}}$, we would have had to do it three times. We’ll show an easier (tabular) way to handle these situations below.

Notice in the second problem, we have to “collect the integrals” since the functions never reduce to $ 0$.

## Tabular Method for Integration by Parts

Instead of performing **Integration of Parts** over and over again (like the problem above), there is a much easier way to solve using a table. These problems typically have $ x$ raised to a power; we have to get that power down to $ 0$ in order to solve. The $ u$-part is typically the variable raised to the power, and the $ v\,dv$-part what we call the “indestructible” part: the part that doesn’t go down to $ 0$ when you keep taking it’s derivative or integral (for example, $ {{e}^{x}}$ or $ \sin x$). **Actually, most integration by parts problem can be solved with the Tabular method!**

Start with the $ u$-part of the equation (again, usually the variable raised to the power), and in the second column, keep taking derivatives until you reach $ 0$. In the next column, start with the “$v\, dv$”-part, and keep taking integrals for every row. Then multiply the second and third columns (ignoring the first term of the third column) and use alternate signs, as shown in the first column (start with a $ +$). Here is an example:

Find $ \displaystyle \int{{{{x}^{3}}}}\cos \left( {2x} \right)\,dx$ using **Integration by Parts** tabular method: $ u={{x}^{3}};\,\,\,\,v\,dv=\cos \left( {2x} \right)\,dx$.

To get the integral, multiply across the arrows of columns two and three, using the signs from column one:

Here’s another example: Find $ \displaystyle \int{{{{x}^{4}}}}{{e}^{{-2x}}}\,dx$ using **Integration by Parts** tabular method: $ u={{x}^{4}};\,\,\,\,v\,dv={{e}^{{-2x}}}\,dx$.

To get the integral, multiply across the arrows of columns two and three, using the signs from column one:

**Understand these problems, and practice, practice, practice!**

On to **Integration by Partial Fractions** – you are ready!

**For Practice**: Use the **Mathway** widget below to try an **Integration by Parts** problem. Click on **Submit** (the blue arrow to the right of the problem) and click on **Evaluate the Integral** to see the answer.

You can also type in your own problem, or click on the three dots in the upper right hand corner and click on “Examples” to drill down by topic.

If you click on **Tap to view steps**, or **Click Here**, you can register at **Mathway** for a **free trial**, and then upgrade to a paid subscription at any time (to get any type of math problem solved!).

**On to Integration by Partial Fractions – you’re ready! **