High School Mathematics Extensions/Supplementary/Polynomial Division

High School Mathematics Extensions

Supplementary Chapters — Primes and Modular Arithmetic — Logic

Mathematical Proofs — Set Theory and Infinite Processes Counting and Generating Functions — Discrete Probability

Matrices — Further Modular Arithmetic — Mathematical Programming

Content
Supplementary Chapters
Basic Counting
Polynomial Division
Partial Fractions
Summation Sign
Complex Numbers
Differentiation
Problems & Projects
Problem Set
Solutions
Exercise Solutions
Problem Set Solutions

Introduction

First of all, we need to incorporate some notions about a much more fundamental concept: factoring.

We can factor numbers,

5\times 7=35

or even expressions involving variables (polynomials),

(x-3)(x+7)=x^{2}+4x-21

Factoring is the process of splitting an expression into a product of simpler expressions. It's a technique we'll be using a lot when working with polynomials.

Dividing polynomials

There are some cases where dividing polynomials may come as an easy task to do, for instance:

{\frac {x^{3}+6x-12}{2x}}

Distributing,

{\frac {x^{3}}{2x}}+{\frac {6x}{2x}}-{\frac {12}{2x}}

Finally,

{\frac {1}{2}}x^{2}+3-{\frac {6}{x}}

Another trickier example making use of factors:

{\frac {2x^{3}+3x^{2}+6x+9}{2x+3}}

Reordering,

{\frac {2x^{3}+6x+3x^{2}+9}{2x+3}}

Factoring,

{\frac {2x(x^{2}+3)+3(x^{2}+3)}{2x+3}}

One more time,

{\frac {(2x+3)(x^{2}+3)}{2x+3}}

Yielding,

x^{2}+3

1. Try dividing  $35x^{2}+29x+6$  by  $2.5x+1$  .

2. Now, can you factor  $P(x)=3x^{3}-9x+6$  ?

Long division

What about a non-divisible polynomials? Like these ones:

(3x^{2}+3x-4)/(x-4)

Sometimes, we'll have to deal with complex divisions, involving large or non-divisible polynomials. In these cases, we can use the long division method to obtain a quotient, and a remainder:

P(x)=Q(x)\times C(x)+R

In this case:

(3x^{2}+3x-4)=Q(x)\times (x-4)+R

Long division method
1	We first consider the highest-degree terms from both the dividend and divisor, the result is the first term of our quotient.	$(3x^{2})/(x)=3x$	${\begin{array}{r\|ccc}x-4&3x^{2}&3x&-4\\\hline \hline &3x^{2}&3x&\\3x(x-4)&3x^{2}&-12x&\\\hline &&15x&-4\\15(x-4)&&15x&-60\\\hline &&&56\\\end{array}}$
2	Then we multiply this by our divisor.	$(3x)\times (x-4)=3x^{2}-12x$
3	And subtract the result from our dividend.	$(3x^{2}+3x-4)-(3x^{2}-12x)=15x-4$
4	Now once again with the highest-degree terms of the remaining polynomial, and we got the second term of our quotient.	$(15x)/(x)=15$
5	Multiplying...	$(15)\times (x-4)=15x-60$
6	Subtracting...	$(15x-4)-(15x-60)=56$
7	We are left with a constant term - our remainder:	${\begin{array}{lcr}Q(x)=3x+15&&R=56\end{array}}$

So finally:

(3x^{2}+3x-4)=(3x+15)\times (x-4)+56

3. Find some  $G(x)$  such that  $(6x^{2}-13x+7)-G(x)$  is divisible by  $(3x+1)$  .

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