# Polynomials - Long Division

A polynomial looks like this:

example of a polynomial this one has 3 terms |

## Dividing

Polynomials can sometimes be divided using the simple methods shown on Dividing Polynomials.

But sometimes it is better to use "Long Division" (a method similar to Long Division for Numbers)

## Numerator and Denominator

We can give each polynomial a name:

- the
**top**polynomial is the**numerator** - the
**bottom**polynomial is the**denominator**

If you have trouble remembering, think **denominator** is **down-**ominator.

## The Method

Write it down neatly:

- the denominator goes first,
- then a ")",
- then the numerator with a line above

Both polynomials should have the "higher order" terms first (those with the largest exponents, like the "2" in x^{2}).

Then:

- Divide the first term of the numerator by the first term of the denominator, and put that in the answer.
- Multiply the denominator by that answer, put that below the numerator
- Subtract to create a new polynomial
| |

Repeat, using the new polynomial |

It is easier to show with an example!

Example:

Write it down neatly like below, then solve it step-by-step (press play):

### Check the answer:

Multiply the answer by the bottom polynomial, we should get the top polynomial:

## Remainders

The previous example worked perfectly, but that is not always so! Try this one:

After dividing we were left with "2", this is the "remainder".

The remainder is what is left over after dividing.

But we still have an answer: put the **remainder divided by the bottom polynomial ** as part of the answer, like this:

## "Missing" Terms

There can be "missing terms" (example: there may be an x^{3}, but no x^{2}). In that case either leave gaps, or include the missing terms with a coefficient of zero.

Example:

Write it down with "0" coefficients for the missing terms, then solve it normally (press play):

See how we needed a space for "3x^{3}" ?

## More than One Variable

So far we have been dividing polynomials with only one variable (**x**), but we can handle polynomials with two or more variables (such as **x** and **y**) using the same method.

Example: