I apologize for the outage on the site yesterday and today. Lamar University is in Beaumont Texas and Hurricane Laura came through here and caused a brief power outage at Lamar. Things should be up and running at this point and (hopefully) will stay that way, at least until the next hurricane comes through here which seems to happen about once every 10-15 years. Note that I wouldn't be too suprised if there are brief outages over the next couple of days as they work to get everything back up and running properly. I apologize for the inconvienence.

Paul

August 27, 2020

*i.e.*you are probably on a mobile phone). Due to the nature of the mathematics on this site it is best views in landscape mode. If your device is not in landscape mode many of the equations will run off the side of your device (should be able to scroll to see them) and some of the menu items will be cut off due to the narrow screen width.

### Section 5-1 : Dividing Polynomials

In this section we’re going to take a brief look at dividing polynomials. This is something that we’ll be doing off and on throughout the rest of this chapter and so we’ll need to be able to do this.

Let’s do a quick example to remind us how long division of polynomials works.

Let’s first get the problem set up.

\[\require{enclose} x-4 \enclose{longdiv}{{5{{x}^{3}}-{{x}^{2}}+0x+6}}\]Recall that we need to have the terms written down with the exponents in decreasing order and to make sure we don’t make any mistakes we add in any missing terms with a zero coefficient.

Now we ask ourselves what we need to multiply \(x - 4\) to get the first term in first polynomial. In this case that is \(5{x^2}\). So multiply \(x - 4\) by \(5{x^2}\) and subtract the results from the first polynomial.

\[\require{enclose}\begin{align*} & \,\,\,5x^{2} \\ x-4 & {\enclose{longdiv}{{5{{x}^{3}}-{{x}^{2}}+0x+6}}} \\ - & \underline{\left( 5{{x}^{3}}-20{{x}^{2}} \right)} \\ & \hspace{0.65in}19{{x}^{2}}+0x+6 \\ \end{align*}\]The new polynomial is called the **remainder**. We continue the process until the degree of the remainder is less than the degree of the **divisor**, which is \(x - 4\) in this case. So, we need to continue until the degree of the remainder is less than 1.

Recall that the **degree** of a polynomial is the highest exponent in the polynomial. Also, recall that a constant is thought of as a polynomial of degree zero. Therefore, we’ll need to continue until we get a constant in this case.

Here is the rest of the work for this example.

\[\require{enclose}\begin{align*} & \,\,\, 5{{x}^{2}}+19x+76 \\ x-4 & {\enclose{longdiv}{{5{{x}^{3}}-{{x}^{2}}+0x+6}}} \\ - & \underline{\left( 5{{x}^{3}}-20{{x}^{2}} \right)} \\ & \hspace{0.65in}19{{x}^{2}}+0x+6 \\ & \hspace{0.4in}-\underline{\left( 19{{x}^{2}}-76x \right)} \\ & \hspace{1.3in}76x+6 \\ & \hspace{1.05in}-\underline{\left( 76x-304 \right)} \\ & \hspace{1.9in}310 \\ \end{align*}\]Okay, now that we’ve gotten this done, let’s remember how we write the actual answer down. The answer is,

\[\frac{{5{x^3} - {x^2} + 6}}{{x - 4}} = 5{x^2} + 19x + 76 + \frac{{310}}{{x - 4}}\]There is actually another way to write the answer from the previous example that we’re going to find much more useful, if for no other reason that it’s easier to write down. If we multiply both sides of the answer by \(x - 4\) we get,

\[5{x^3} - {x^2} + 6 = \left( {x - 4} \right)\left( {5{x^2} + 19x + 76} \right) + 310\]In this example we divided the polynomial by a linear polynomial in the form of \(x - r\) and we will be restricting ourselves to only these kinds of problems. Long division works for much more general division, but these are the kinds of problems we are going to seeing the later sections.

In fact, we will be seeing these kinds of divisions so often that we’d like a quicker and more efficient way of doing them. Luckily there is something out there called **synthetic division** that works wonderfully for these kinds of problems. In order to use synthetic division we must be dividing a polynomial by a linear term in the form \(x - r\). If we aren’t then it won’t work.

Let’s redo the previous problem with synthetic division to see how it works.

Okay with synthetic division we pretty much ignore all the \(x\)’s and just work with the numbers in the polynomials.

First, let’s notice that in this case *r=4*.

Now we need to set up the process. There are many different notations for doing this. We’ll be using the following notation.

\[\left. {\underline {\,4 \,}}\! \right| \,\,\,\begin{array}{*{20}{l}}5&{ - 1}&0&6\end{array}\]The numbers to the right of the vertical bar are the coefficients of the terms in the polynomial written in order of decreasing exponent. Also notice that any missing terms are acknowledged with a coefficient of zero.

Now, it will probably be easier to write down the process and then explain it so here it is.

The first thing we do is drop the first number in the top line straight down as shown. Then along each diagonal we multiply the starting number by \(r\) (which is 4 in this case) and put this number in the second row. Finally, add the numbers in the first and second row putting the results in the third row. We continue this until we get reach the final number in the first row.

Now, notice that the numbers in the bottom row are the coefficients of the quadratic polynomial from our answer written in order of decreasing exponent and the final number in the third row is the remainder.

The answer is then the same as the first example.

\[5{x^3} - {x^2} + 6 = \left( {x - 4} \right)\left( {5{x^2} + 19x + 76} \right) + 310\]We’ll do some more examples of synthetic division in a bit. However, we really should generalize things out a little first with the following fact.

#### Division Algorithm

Given a polynomial \(P(x)\) with degree at least 1 and any number \(r\) there is another polynomial \(Q(x)\), called the **quotient**, with degree one less than the degree of \(P(x)\) and a number \(R\), called the **remainder**, such that,

Note as well that \(Q(x)\) and \(R\) are unique, or in other words, there is only one \(Q(x)\) and \(R\) that will work for a given \(P(x)\) and \(r\).

So, with the one example we’ve done to this point we can see that,

\[Q\left( x \right) = 5{x^2} + 19x + 76\hspace{0.25in}{\mbox{and}}\hspace{0.25in}R = 310\]Now, let’s work a couple more synthetic division problems.

- \(2{x^3} - 3x - 5\) by \(x + 2\)
- \(4{x^4} - 10{x^2} + 1\) by \(x - 6\)

Okay in this case we need to be a little careful here. We MUST divide by a term in the form \(x - r\) in order for this to work and that minus sign is absolutely required. So, we’re first going to need to write \(x + 2\) as,

\[x + 2 = x - \left( { - 2} \right)\]and in doing so we can see that \(r = - 2\).

We can now do synthetic division and this time we’ll just put up the results and leave it to you to check all the actual numbers.

\[\begin{align*} \left. {\underline {\,{ - 2} \,}}\! \right| & \begin{array}{*{20}{l}}2&{0}&{ - 3}&{- 5}\end{array}\\ & \underline {\begin{array}{*{20}{l}}{}&{ - 4}&{\,\,8}&{ - 10}\end{array}} \\ & \begin{array}{*{20}{l}}{2}&{ - 4}&{5}&{ - 15}\end{array}\end{align*}\]So, in this case we have,

\[2{x^3} - 3x - 5 = \left( {x + 2} \right)\left( {2{x^2} - 4x + 5} \right) - 15\]b \(4{x^4} - 10{x^2} + 1\) by \(x - 6\) Show Solution

In this case we’ve got \(r\)=6. Here is the work.

\[\begin{align*}\left. {\underline {6 \,}}\! \right| & \begin{array}{*{20}{l}}4&{\,0}&{ - 10}&{\,\,\,\,\,\,0}&{\,\,\,\,\,\,\,\,\,\,1}\end{array}\\ & \underline {\begin{array}{*{20}{l}}0&{24}&{144}&{804}&{4824}\end{array}} \\ & \begin{array}{*{20}{l}}4&{24}&{134}&{804}&{4825}\end{array}\end{align*}\]In this case we then have.

\[4{x^4} - 10{x^2} + 1 = \left( {x - 6} \right)\left( {4{x^3} + 24{x^2} + 134x + 804} \right) + 4825\]So, just why are we doing this? That’s a natural question at this point. One answer is that, down the road in a later section, we are going to want to get our hands on the \(Q(x)\). Just why we might want to do that will have to wait for an explanation until we get to that point.

There is also another reason for this that we are going to make heavy usage of later on. Let’s first start out with the division algorithm.

\[P\left( x \right) = \left( {x - r} \right)Q\left( x \right) + R\]Now, let’s evaluate the polynomial \(P(x)\) at \(r\). If we had an actual polynomial here we could evaluate \(P(x)\) directly of course, but let’s use the division algorithm and see what we get,

\[\begin{align*}P\left( r \right) & = \left( {r - r} \right)Q\left( r \right) + R\\ & = \left( 0 \right)Q\left( r \right) + R\\ & = R\end{align*}\]Now, that’s convenient. The remainder of the division algorithm is also the value of the polynomial evaluated at \(r\). So, from our previous examples we now know the following function evaluations.

\[\begin{align*}& {\mbox{If}}\,\,P\left( x \right) = 5{x^3} - {x^2} + 6\,\,{\mbox{then }}P\left( 4 \right) = 310\\ & {\mbox{If}}\,\,P\left( x \right) = 2{x^3} - 3x - 5\,\,{\mbox{then }}P\left( { - 2} \right) = - 15\\ & {\mbox{If}}\,\,P\left( x \right) = 4{x^4} - 10{x^2} + 1\,\,{\mbox{then }}P\left( 6 \right) = 4825\end{align*}\]This is a very quick method for evaluating polynomials. For polynomials with only a few terms and/or polynomials with “small” degree this may not be much quicker that evaluating them directly. However, if there are many terms in the polynomial and they have large degrees this can be much quicker and much less prone to mistakes than computing them directly.

As noted, we will be using this fact in a later section to greatly reduce the amount of work we’ll need to do in those problems.