unit 8: factoring quadratics and operating with radicals
TRANSCRIPT
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Unit 8: Factoring Quadratics and Operating with Radicals
I CAN:
o Factor expressions by GCF
o Factor a quadratic expression when a=1
o Factor a quadratic expression when aβ 1
o Factor a difference of squares
o Factor completely using all factoring strategies
o Solve a quadratic equation by factoring
o Simplify radical expressions with integer and variable radicands
o Add and subtract radical expressions
o Multiply radicals and divide/rationalize the denominator
*THIS PLAN IS SUBJECT TO CHANGE. CHECK DAILY NOTES AND BLOG FOR UPDATES.*
Monday Tuesday Wednesday Thursday Friday 4 Factoring GCF
and Trinomials with
a=1
5 Factoring
trinomials when
aβ 1
6 More Practice
Factoring Trinomials
and Difference of
Squares
7 Quiz 8 Happy Friday!
11 Solving
Quadratic
Equations by
Factoring
12 Simplifying
Radicals
13 Adding &
Subtracting
Radicals
14 Multiplying
Radicals and
Rationalizing the
Denominator
15 Happy Friday!
18 Review / Unit 8
Test
19 20 21 22
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Solving Quadratic Equations by Factoring
How to Factor
Warm up: Recall multiplying polynomialsβ¦DISTRIBUTE TO MULTIPLY.
a) 2π₯(4π₯ β 3) b) (π₯ + 5)(π₯ + 2)
The process of factoring is the reverse of the process of distributing.
The goal is to write an expression that is equivalent to the original, by dividing and
βundistributingβ any common factors.
FIRST: GREATEST COMMON FACTOR
For every factoring problem, you should begin by looking for a _______________.
Ex 1: Factor each expression.
a. 2π₯2 + 8π₯ b. 15π₯2 β 35π₯
NEXT: After you have checked for a GCF, your strategy will depend on the number of terms in
the polynomial.
THREE TERMS β SUM & PRODUCT STRATEGIES
When π = π:
If the trinomial is a quadratic expression in standard form, _____________________________,
AND π = π, find two factors of ____ which have a sum equal to ____: then write the quadratic
as the product of two binomial factors (π₯ + π)(π₯ + π).
Ex 2: Factor each trinomial
a. π₯2 + 7π₯ + 12 b. π₯2 β 10π₯ + 25
c. 2π₯2 + 4π₯ β 70 d. 5π₯2 β 20π₯ β 225
sum
product
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When π β π: SLIDE AND DIVIDE
1) Multiply π β π
2) Find two factors of π β π that have a sum equal to π
3) Set up two binomial factors: (π₯ + π)(π₯ + π) 4) Divide π and π by πβ¦then simplify.
Ex 3: Factor each trinomial
a. 2π₯2 β 9π₯ β 18 b. 8π₯2 β 30π₯ + 7
c. 6π₯2 β 5π₯ β 4 d. 3π₯2 β 20π₯ + 32
TWO TERMS - DIFFERENCE OF SQUARES:
This is also a sum & product strategy, but notice that the value of the b-term in each
example below is _______________, therefore the sum of the factors must be _______________.
Ex 4: Factor each binomial
a. π₯2 β 9 b. π₯2 β 100
c. π₯2 β 81 d. π₯2 β 4
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What pattern do you notice about the factors of a difference of squares?
Ex 5: Use this pattern to factor the following
e. 25π₯2 β 49 f. 100π₯2 β 121
g. 16π₯2 β 1 h. π₯2 + 25
i. Using multiple strategies: 3π₯2 β 75
Solving Quadratic Equations by Factoring
According to the Zero Product Property, if the product of two quantities is equal to zero, then
one of the quantities must equal zero.
Step 1: Arrange terms in standard form
Step 2: Factor
Step 3: Set each factor = 0
Step 4: Solve each mini-equation
Ex 6: Solve each equation by factoring.
a. π₯2 + 3π₯ β 40 = 0 b. π₯2 β 9π₯ = 0
c. π₯2 β 3π₯ β 28 = 0 d. 81π₯2 β 100 = 0
Recall: Factoring Strategies
β’ Look for a GCF first!
β’ 2 terms: Difference of Squares?
β’ 3 terms: Sum & Product or Slide & Divide
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e. 2π₯2 β 24π₯ = β72 f. 3π₯2 β 8π₯ + 4 = 0
g. 6π₯ + 16 = π₯2 + 9 h. 5π₯2 + 20π₯ + 20 = 0
i. 15π₯2 β 10π₯ = 0 j. 18π₯2 + 25π₯ β 3 = 0
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Radical Expressions
Perfect
Square: π₯2
Square
Roots:
βπ₯2
Simplifying Radicals
A radical expression is simplified when there areβ¦
1 no perfect square factors (other than 1) in the radicand
2 no fractions under the radical
3 no radicals in the denominator
To Simplify:
β’ Find the biggest perfect square factor of the radicand and evaluate its square root,
bringing it outside the radical.
β’ The product of the remaining non-perfect-square factors will stay inside the radical.
Ex 1: Simplify each radical WITHOUT USING A CALCULATOR
a. β16 b. β8 c. β75
d. β40 e. β45 f. β600
When we simplify radicals, we are finding perfect squares β or PAIRS β of factors.
We will use a similar process to simplify radicals containing variables.
Ex 2: Simplify
a. β4π₯2 b. β98π4π10 c. β27π§3
d. β48π₯π¦5π§9 e. β100π₯12π¦7 f. β180π3π6
βπ
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Adding and Subtracting Radical Expressions
To simplify radical expressions involving addition and subtraction, we must combine βlike
radicals,β which have identical radicands.
When adding and subtracting radicals, we will:
β’ Simplify each radical expression
β’ Combine the like radicals by adding or subtracting their coefficients, keeping the like
radicand the same
Ex 4: Simplify
a. β3 + 5β3 b. 2β6 + β24
c. 3β2 + β5 β 4β8 d. 9β40 β β300 β β90
e. β72 β 4β18 f. β20 + 2β6 β β80
Multiplying Radical Expressions
When multiplying two radicals, we will multiply OUTSIDE β’ OUTSIDE and INSIDE β’ INSIDE, then
simplify.
Ex 5: Simplify
a. β2 β 5β6 b. 3β2 β 5β10
c. β3(2 β β3) d. 2β6 β β48
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e. (5 + β6)(2 β β2) f. (β4 + β6)(β1 β β6)
g. (2 β β3)(2 + β3) h. (10 + β2)(10 β β2)
Dividing with Radical Expressions & Rationalizing the Denominator
Simplify OUTSIDE/OUTSIDE and INSIDE/INSIDE, then rationalize the denominator to eliminate
radicals from the bottom of the fraction, as needed. Simplify again, if necessary.
Ex 6: Simplify
a. β10
β5 b.
2β15
β3
c. 5
β5 d.
β3
β6
e. 6β2
2β5 f. β
9
β3
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