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Polynomial And Rational Functions
Copyright © Cengage Learning. All rights reserved.

2. 3.6 Complex Zeros And The Fundamental Theorem Of Algebra
Copyright © Cengage Learning. All rights reserved.

3. Objectives
The Fundamental Theorem of Algebra and Complete Factorization
Zeros and Their Multiplicities
Complex Zeros Come in Conjugate Pairs
Linear and Quadratic Factors

4. The Fundamental Theorem of Algebra and Complete Factorization

5. The Fundamental Theorem of Algebra and Complete Factorization
The following theorem is the basis for much of our work in factoring polynomials and solving polynomial equations.
Because any real number is also a complex number, the theorem applies to polynomials with real coefficients as well.

6. The Fundamental Theorem of Algebra and Complete Factorization
The Fundamental Theorem of Algebra and the Factor Theorem together show that a polynomial can be factored completely into linear factors,

7. Example 1 – Factoring a Polynomial Completely
Let P (x) = x3 – 3x2 + x – 3. (a) Find all the zeros of P.
(b) Find the complete factorization of P.
Solution: (a) We first factor P as follows.
P (x) = x3 – 3x2 + x – 3
= x2(x – 3) + (x – 3)
Given
Group terms

8. Example 1 – Solution = (x – 3)(x2 + 1)
cont’d
= (x – 3)(x2 + 1)
We find the zeros of P by setting each factor equal to 0:
P (x) = (x – 3)(x2 + 1)
Setting x – 3 = 0, we see that x = 3 is a zero. Setting x2 + 1 = 0, we get x2 = –1, so x = i. So the zeros of P are 3, i, and –i.
Factor x – 3

9. Example 1 – Solution
cont’d
(b) Since the zeros are 3, i, and –i, by the Complete Factorization Theorem P factors as
P (x) = (x – 3)(x – i) [x – (–i)]
= (x – 3)(x – i) (x + i)

10. Zeros and Their Multiplicities

11. Zeros and Their Multiplicities
In the Complete Factorization Theorem the numbers c1, c2, , cn are the zeros of P. These zeros need not all be different. If the factor x – c appears k times in the complete factorization of P (x), then we say that c is a zero of multiplicity k. For example, the polynomial P (x) = (x – 1)3(x + 2)2(x + 3)5 has the following zeros: 1 (multiplicity 3), –2 (multiplicity 2), –3 (multiplicity 5)

12. Zeros and Their Multiplicities
The polynomial P has the same number of zeros as its degree: It has degree 10 and has 10 zeros, provided that we count multiplicities. This is true for all polynomials, as we prove in the following theorem.

13. Zeros and Their Multiplicities
The following table gives further examples of polynomials with their complete factorizations and zeros.

14. Example 4 – Finding Polynomials with Specified Zeros
(a) Find a polynomial P (x) of degree 4, with zeros i, –i, 2, and –2, and with P (3) = 25. (b) Find a polynomial Q (x) of degree 4, with zeros –2 and , where –2 is a zero of multiplicity 3.
Solution: (a) The required polynomial has the form P (x) = a(x – i )(x – (–i ))(x – 2)(x – (–2))
= a(x2 + 1)(x2 – 4)
Difference of squares

15. Example 4 – Solution = a(x4 – 3x2 – 4)
cont’d
= a(x4 – 3x2 – 4)
We know that P (3) = a(34 – 3  32 – 4) = 50a = 25, so a = . Thus, P (x) = x4 – x2 – 2
(b) We require Q (x) = a [x – (–2)]3(x – 0)
= a (x + 2)3x
Multiply

16. Example 4 – Solution = a(x3 + 6x2 + 12x + 8)x
cont’d
= a(x3 + 6x2 + 12x + 8)x
= a(x4 + 6x3 + 12x2 + 8x)
Since we are given no information about Q other than its zeros and their multiplicity, we can choose any number for a.
If we use a = 1, we get Q (x) = x4 + 6x3 + 12x2 + 8x
(A + B)3 = A3 + 3A2B + 3AB2 + B3

17. Complex Zeros Come in Conjugate Pairs

18. Complex Zeros Come in Conjugate Pairs
As you might have noticed from the examples so far, the complex zeros of polynomials with real coefficients come in pairs. Whenever a + bi is a zero, its complex conjugate a – bi is also a zero.

19. Example 6 – A Polynomial with a Specified Complex Zero
Find a polynomial P (x) of degree 3 that has integer coefficients and zeros and 3 – i.
Solution: Since 3 – i is a zero, then so is 3 + i by the Conjugate Zeros Theorem. This means that P (x) must have the following form.
P (x) = a (x – )[x – (3 – i)] [x – (3 + i)]
= a (x – )[(x – 3) + i ] [(x – 3) + i ]
Regroup

20. Example 6 – Solution = a (x – )[(x – 3)2 – i2]
cont’d
= a (x – )[(x – 3)2 – i2]
= a (x – )(x2 – 6x + 10)
= a (x3 – x2 + 13x – 5 )
To make all coefficients integers, we set a = 2 and get
P (x) = 2x3 – 13x2 + 26x – 10
Any other polynomial that satisfies the given requirements must be an integer multiple of this one.
Difference of Squares Formula
Expand
Expand

21. Linear and Quadratic Factors

22. Linear and Quadratic Factors
We have seen that a polynomial factors completely into linear factors if we use complex numbers. If we don’t use complex numbers, then a polynomial with real coefficients can always be factored into linear and quadratic factors. We use this property when we study partial fractions. A quadratic polynomial with no real zeros is called irreducible over the real numbers. Such a polynomial cannot be factored without using complex numbers.

23. Linear and Quadratic Factors

24. Example 7 – Factoring a Polynomial into Linear and Quadratic Factors
Let P (x) = x4 + 2x2 – 8. (a) Factor P into linear and irreducible quadratic factors with real coefficients.
(b) Factor P completely into linear factors with complex coefficients.
Solution: (a) P (x) = x4 + 2x2 – 8
= (x2 – 2)(x2 + 4)

25. Example 7 – Solution = (x – )(x + )(x2 + 4)
cont’d
= (x – )(x )(x2 + 4)
The factor x2 + 4 is irreducible, since it has no real zeros.
(b) To get the complete factorization, we factor the remaining quadratic factor.
P (x) = (x – )(x )(x2 + 4)
= (x – )(x )(x – 2i)(x + 2i)