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3.4 Zeros of Polynomial Functions

3.4 Zeros of Polynomial Functions. The Fundamental Theorem of Algebra. If f(x) is a polynomial of degree n , where n>0, then f has at least one zero in the complex number system. Linear Factorization Theorem.

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3.4 Zeros of Polynomial Functions

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  1. 3.4 Zeros of Polynomial Functions

  2. The Fundamental Theorem of Algebra If f(x) is a polynomial of degree n, where n>0, then f has at least one zero in the complex number system.

  3. Linear Factorization Theorem If f(x) is a polynomial of degree n, where n>0, then f has precisely n linear factors : where are complex numbers.

  4. Consider the following n degree polynomials and their solutions: Function Solutions

  5. The Rational Zero Test If the polynomial has integer coefficients, every rational zero of f has the form: Rational Zero= , where p and q have no common factors other than 1, and p is a factor of the constant term and q is a factor of the leading coefficient .

  6. Find the rational zeros.

  7. Complex Zeros Occur in Conjugate Pairs Let f(x) be a polynomial function that has real coefficients. If a+bi, where , is a zero of the function, the conjugate a-bi is also a zero of the function. Ex. Find a fourth degree polynomial with real coefficients that has as zeros.

  8. Find the zeros of the polynomial and write the polynomial as the product of factors. given that 1+3i is a given zero.

  9. Factoring a Polynomial The linear factorization theorem says we can factor any nth-degree polynomial as a product of n linear terms. Here’s where it gets a little tricky…

  10. A quadratic factor with no real zeros (previously called prime but now) is Irreducible over the Reals Example: It is irreducible over the reals (and therefore over the rationals). Another example: Is irreducible over the rationals but reducible over the reals

  11. Find all of the Zeros

  12. Descartes’s Rule of Signs Let be a polynomial with real coefficients and 1- The number of positivereal zeros of f is either equal to the number of variations in sign of f(x) or less than that number by an even integer 2- The number of negative real zeros of f is equal to the number of variations in sign of f(-x) or less than that number by an even integer

  13. Examples

  14. Upper and Lower Bound Rules Let f(x) be a polynomial with real coefficients and a positive leading coefficient. Suppose f(x) is divided by x – c, using synthetic division. 1- If c>0 and each number in the last row is either positive or zero, c is an upper bound for the real zeros of f 2- If c<0 and the numbers in the last row are alternately positive and negative (zero entries can count as positive or negative), c is a lower bound for the real zeros of f.

  15. What good are these new rules? They can help narrow down the possible rational roots that you have to choose from. Find the real zeros of

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