Recall: Difference of Squares Identity
- Identity:
- Example:
— check by expanding - Key move: middle terms cancel; only perfect squares remain
Can you factor
Can You Factor ?
Over the reals: No. The discriminant is
Over the complex numbers: Yes.
Check:
Difference vs. Sum of Squares: The Parallel
Difference of squares (real):
Sum of squares (complex):
Replace
Derivation: Why the Identity Works
Key step:
Middle terms cancel; only the i² step differs from difference of squares.
Worked Example: The Canonical Case
Identify:
Apply:
Verify:
Three More Sum-of-Squares Factoring Examples
Quick Check: Factor Using Sum of Squares
Factor each expression over the complex numbers:
Root-to-Factor: The Connection to CN.C.7
Factor Theorem: If
This works for complex
From Roots to Factored Form
For roots
Cross-terms cancel; product is real-coefficient.
Worked Example:
Roots:
Factored form:
Verify:
Worked Example:
Roots:
Factored form:
Quick Check: Roots to Factored Form
-
The roots of
are . Write the factored form and verify. -
The roots of
are . Write the factored form.
Error Hunt: Two Mistakes to Find
Student 1 factors
Student 2 factors
Identify each error. Write the correct factorization.
Every Polynomial Factors Completely Over
For any polynomial of degree
- Exactly
roots exist over (counting multiplicity) - Complex roots come in conjugate pairs
- Odd-degree polynomials must have at least one real root
This is the preview of the Fundamental Theorem of Algebra (CN.C.9).
Factor Completely Over
Step 1:
Step 2: Roots of
Full factorization:
Three linear factors for degree 3.
Three Problems With No Scaffolding
-
Factor
over the complex numbers. -
The roots of
are . Write the factored form. -
Factor
completely over .
Watch for These Three Common Errors
-
Sign error:
— sum of squares uses , not real numbers -
Same-sign error:
— conjugate pair needed: -
Verification skip: always expand to confirm — complex factors must produce real coefficients
What You Now Know: Complex Polynomial Identities
✓ Sum of squares:
✓ Root-to-factor: if
✓ Conjugate pairs always multiply to real coefficients
Sum of squares needs
Use
Next: Fundamental Theorem of Algebra
In HSN.CN.C.9, you'll see the theorem made explicit:
Every non-constant polynomial with complex coefficients has at least one complex root.
This lesson showed the pattern. CN.C.9 proves it applies to every polynomial — including higher-degree cases beyond quadratics and cubics.