Post on 24-Dec-2015
Polynomial Long and Synthetic DivisionPre-Calculus
Plan for the section 2.3
2.3 Polynomial Division Synthetic Division Remainder Theorem Factor Theorem Using Division to Factor / Find Zeros
Homework
• Use long division to divide polynomials by other polynomials.
• Use synthetic division to divide polynomials by binomials of the form (x – k).
• Use the Remainder Theorem and the Factor Theorem.
What You Should Learn
When our factoring techniques do not easily work… Analyzing and Graphing a Function
Let’s say we want to analyze this function and graph it:f(x) = x7 - 8x5 - 2x4 - 21x3 + 10x2 + 108x + 72 We know the left and right behavior We know the y- intercept To get a good approximation of the graph, we need to know the
x-intercepts or the “zeros”. To find all the real zeros of the function we must factor it completely.
Determining if one polynomial is a factor of another polynomial
Factoring a polynomial Polynomial division will help with this.
Today
We are going to learn about the process of division
Learn about a couple of theorems to help in factoring and solving higher level polynomials
Division of Polynomials In this section, we will study two procedures for
dividing polynomials.
These procedures are especially valuable in factoring and finding the zeros of polynomial functions.
Polynomial Division
Polynomial Division is very similar to long division.
Example:
13
31053 23
x
xxx
Polynomial Division
3105313 23 xxxx
2x
233 xx 26x x10
x2
xx 26 2 x12 3
4
x12 4
7
13
7
x
Subtract!!
Subtract!!
Subtract!!
Polynomial Division
Example:
Notice that there is no x term. However, we need to include it when we divide.
52
1592 23
x
xx
Polynomial Division
159252 23 xxx
2x
23 52 xx 24x x0
x2
xx 104 2 x10 15
5
x10 25
10
52
10
x
x0
Try This
Example:
Answer:
2
349105 234
x
xxxx
1743 23 xxx
What does it mean if a number divides evenly into another?? No remainder Remainder = 0 The Quotient is the FACTOR of the
polynomial (Factor Theorem)
Now let’s look at another method to divide… Why??? Sometimes it is easier…
Synthetic Division
Synthetic Division is a ‘shortcut’ for polynomial division that only works when dividing by a linear factor (x - k).
It involves the coefficients of the dividend, and the zero of the divisor.
Synthetic Division
The pattern for synthetic division of a cubic polynomial is summarized as follows. (The pattern for higher-degree polynomials is similar.)
Synthetic Division
This algorithm for synthetic division works only for divisors of the form x – k.
Remember that x + k = x – (–k).
ExampleExample
Divide:Divide: Step 1:Step 1:
Write the Write the coefficientscoefficients of the dividend in a of the dividend in a upside-down division symbol.upside-down division symbol.
1 5 6
1
652
x
xx
ExampleExample
Step 2:Step 2: Take the Take the zerozero of the divisor, and write it on of the divisor, and write it on
the left.the left. The divisor is x – 1, so the zero is 1.The divisor is x – 1, so the zero is 1.
1 5 61
1
652
x
xx
ExampleExample
Step 3:Step 3: Carry down the first coefficient.Carry down the first coefficient.
1 5 61
1
1
652
x
xx
ExampleExample
Step 4:Step 4: Multiply the zero by this number. Write the Multiply the zero by this number. Write the
product under the next coefficient.product under the next coefficient.
1 5 61
1
1
1
652
x
xx
ExampleExample
Step 5:Step 5: Add.Add.
1 5 61
1
1
6
1
652
x
xx
ExampleExample
Step etc.:Step etc.: Repeat as necessaryRepeat as necessary
1 5 61
1
1
6
6
12
1
652
x
xx
ExampleExample
The numbers at the bottom represent the The numbers at the bottom represent the coefficients of the answer. The new coefficients of the answer. The new polynomial will be one degree less than polynomial will be one degree less than the original.the original.
1 5 61
1
1
6
6
12 1
126
x
x
1
652
x
xx
Using Synthetic Division
Use synthetic division to divide x4 – 10x2 – 2x + 4 by x + 3.
Solution:
You should set up the array as follows. Note that a zero is included for the missing x3-term in the dividend.
Example – Solution
Then, use the synthetic division pattern by adding terms in columns and multiplying the results by –3.
So, you have
.
cont’d
Try These
Examples:(x4 + x3 – 11x2 – 5x + 30) (x – 2)(x4 – 1) (x + 1)
[Don’t forget to include the missing terms!]
Answers:x3 + 3x2 – 5x – 15x3 – x2 + x – 1
Application of Long Division
To begin, suppose you are given the graph of
f (x) = 6x3 – 19x2 + 16x – 4.
Long Division of Polynomials
Notice that a zero of f occurs at x = 2.
Because x = 2 is a zero of f,you know that (x – 2) isa factor of f (x). This means thatthere exists a second-degree polynomial q (x) such that
f (x) = (x – 2) q(x).
To find q(x), you can uselong division.
Example - Long Division of Polynomials
Divide 6x3 – 19x2 + 16x – 4 by x – 2, and use
the result to factor the polynomial
completely.
Example 1 – SolutionThink
Think
Think
Multiply: 6x2(x – 2).
Subtract.
Multiply: 2(x – 2).
Subtract.
Multiply: –7x(x – 2).
Subtract.
Example – Solution
From this division, you can conclude that
6x3 – 19x2 + 16x – 4 = (x – 2)(6x2 – 7x + 2)
and by factoring the quadratic 6x2 – 7x + 2,
you have
6x3 – 19x2 + 16x – 4 =
(x – 2)(2x – 1)(3x – 2).
cont’d
Long Division of Polynomials
The Remainder and Factor Theorems
The Remainder and Factor Theorems
The remainder obtained in the synthetic division process has an important interpretation, as described in the Remainder Theorem.
The Remainder Theorem tells you that synthetic division can be used to evaluate a polynomial function. That is, to evaluate a polynomial function f (x) when x = k, divide f (x) by x – k. The remainder will bef (k).
Example Using the Remainder Theorem
Use the Remainder Theorem to evaluate the following function at x = –2.
f (x) = 3x3 + 8x2 + 5x – 7
Solution: Using synthetic division, you obtain the following.
Example – Solution
Because the remainder is r = –9, you can conclude that
f (–2) = –9.
This means that (–2, –9) is a point on the graph of f. You can check this by substituting x = –2 in the original function.
Check:
f (–2) = 3(–2)3 + 8(–2)2 + 5(–2) – 7
= 3(–8) + 8(4) – 10 – 7
= –9
r = f (k)
cont’d
The Remainder and Factor Theorems
Another important theorem is the Factor Theorem, stated below.
This theorem states that you can test to see whether a polynomial has (x – k) as a factor by evaluating the polynomial at x = k.
If the result is 0, (x – k) is a factor.
Example – Factoring a Polynomial: Repeated Division
Show that (x – 2) and (x + 3) are factors of
f (x) = 2x4 + 7x3 – 4x2 – 27x – 18.
Then find the remaining factors of f (x).
Solution:Using synthetic division with the factor (x – 2), you obtain the following.
0 remainder, so f (2) = 0and (x – 2) is a factor.
Example – Solution
Take the result of this division and perform synthetic division again using the factor (x + 3).
Because the resulting quadratic expression factors as
2x2 + 5x + 3 = (2x + 3)(x + 1)
the complete factorization of f (x) is
f (x) = (x – 2)(x + 3)(2x + 3)(x + 1).
0 remainder, so f (–3) = 0and (x + 3) is a factor.
cont’d
The Remainder and Factor Theorems
For instance, if you find that x – k divides evenly into f (x) (with no remainder), try sketching the graph of f.
You should find that (k, 0) is an x-intercept of the graph.
• Use long division to divide polynomials by other polynomials.
• Use synthetic division to divide polynomials by binomials of the form (x – k).
• Use the Remainder Theorem and the Factor Theorem.
Can you…