Recall: Division and Polynomial Evaluation
- Division algorithm:
(dividend = divisor × quotient + remainder) - Remainder: the constant left over — not the quotient
- Evaluate
: substitute into
Quick check: what is
What Is the Remainder When You Divide?
Integer division:
Check:
Polynomial division: divide
Can you find it without doing the full division?
Integer and Polynomial Division: Same Structure
| Integer | Polynomial | |
|---|---|---|
| equation | ||
| divisor | ||
| quotient | ||
| remainder | constant |
Remainder Is Always a Constant Here
When
- Remainder degree
: so is a constant - Identity holds for every
— pick
Long Division Confirms the Structure
Divide
Remainder = 7
Now evaluate directly:
Quick Check: Long Division Practice
Divide
- What is the quotient?
- What is the remainder?
- Verify: evaluate
and confirm it equals your remainder.
Try it before moving on.
The Remainder Theorem: No Division Needed
Remainder Theorem: For any polynomial
The remainder when
is divided by equals .
Shortcut: To find the remainder — just evaluate
The Proof Walks Through One Step
The division equation is true for all
Substitute
Therefore:
Remainder Theorem: First Worked Example
Find the remainder when
By the Remainder Theorem: remainder
Remainder
(No long division needed.)
Remainder Theorem Example Two: Sign Alert
Find the remainder when
Remainder
Divisor
Remainder Theorem: Third Worked Example
Find the remainder when
Remainder
Missing powers (like
Find the Sign Error in This Solution
A student evaluates the remainder when
"Remainder = p(3) = 27 − 15 + 1 = 13"
What is wrong? What should the student have done?
Identify the error and give the correct remainder.
Practice: Apply the Remainder Theorem Now
Find the remainder when
- What is
? - Evaluate
— that is the remainder.
No division needed.
Factor Theorem: Zeros Equal Factors
Factor Theorem (corollary of Remainder Theorem):
- If:
remainder exact division - Only-if:
Test Both Directions of the Factor Theorem
Direction 1:
Direction 2: Is
Decide Direction 1 before advancing.
Factor Theorem: Factoring a Cubic
Factor
Divide → quotient
Factoring When Leading Coefficient Isn't One
Factor
Quotient:
Zeros:
Rational Root Theorem: Finite Candidates
Rational zero
For
From Factor Theorem to Synthetic Division
Factor Theorem: confirms a factor exists.
Synthetic division: computes the quotient.
- Divide out
to reduce the degree - Final number always equals
— built-in check
Synthetic Division: The Layout and Steps
Divide
- Write
at left; coefficients across the top - Bring down → multiply by
→ add → repeat
Last number = remainder =
Synthetic Division: Walk Through the Steps
Divide
Quotient:
Synthetic Division: When Remainder Is Zero
Remainder
Your Turn: Factor This Cubic Completely
- Find a zero using the Factor Theorem.
- Use synthetic division to get the quotient.
- Factor the quotient.
No hints — do the full procedure yourself.
Two Zeros: Partial Factored Form
Suppose you test
Without computing the full factorization: what do you know about the factored form of
Write the partial form. How many total factors does a cubic have?
Three Common Errors to Watch For
Wrong sign:
Bottom row: last number = remainder; rest = quotient
RRT isn't exhaustive: no rational roots ≠ no real roots
Evaluation and Division Are Connected
✓ Remainder Theorem: dividing
✓ Factor Theorem:
✓ Workflow: find zero → name factor → divide → factor quotient
Next: Zeros Reveal the Graph's Shape
You can now find all zeros of a polynomial using the Factor Theorem.
The next question: what does the graph do near each zero?
- Cross the
-axis, or bounce off it?
That depends on how many times each factor appears.
APR.B.3 — Graphing Polynomials from Zeros
Click to begin the narrated lesson
Apply the Remainder Theorem