Section 29 number 17 15. α- π', F = Φ(π)16. a = 7², F = Q(7³)17. Refer to Example 29.19 of the text. The polynomial x2+x +1 has a zero a in Z2(a) and thus must factor intoa product of linear factors in (Z2(@))[x]. Find this factorization. [Hint: Divide x² + x + 1 by x-a by longdivision, using the fact that a2 = a + 1.]18. a. Show that the polynomial x2 +1 is irreducible in Z3[x].b. Let a be a zero of x2 +1 in an extension field of Z3. As in Example 29.19, give the multiplication andudan 0 1 a

Name: Section 29 number 17 15. α- π', F = Φ(π)16. a = 7², F = Q(7³)17. Refer
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Description: Section 29 number 17 15. α- π', F = Φ(π)16. a = 7², F = Q(7³)17. Refer to Example 29.19 of the text. The polynomial x2+x +1 has a zero a in Z2(a) and thus must factor intoa product of linear factors in (Z2(@))[x]. Find this factorization. [Hint: Divi

Answered: 17. Refer to Example 29.19 of the text.…

Advanced Engineering Mathematics

10th Edition

ISBN:9780470458365

Author:Erwin Kreyszig

Publisher:Erwin Kreyszig

Chapter2: Second-order Linear Odes

Section: Chapter Questions

Problem 1RQ

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Section 29 number 17

15. α- π', F = Φ(π)
16. a = 7², F = Q(7³)
17. Refer to Example 29.19 of the text. The polynomial x2+x +1 has a zero a in Z2(a) and thus must factor into
a product of linear factors in (Z2(@))[x]. Find this factorization. [Hint: Divide x² + x + 1 by x-a by long
division, using the fact that a2 = a + 1.]
18. a. Show that the polynomial x2 +1 is irreducible in Z3[x].
b. Let a be a zero of x2 +1 in an extension field of Z3. As in Example 29.19, give the multiplication and
udan 0 1 a

Expert Solution

Step 1

The polynomial $x^{2} + x + 1$ has a zero $α$ in $ℤ_{2} (α)$ .

Since the polynomial has a root in $ℤ_{2} (α)$ , it is reducible in $ℤ_{2} (α)$ .

Hence the polynomial can be factored as linear polynomials whose roots are same as the given polynomial.

$x^{2} + x + 1 = g (x) h (x)$

where $g (x)$ and $h (x)$ are linear polynomials.

Since $α$ is a one root of the polynomial, one of the linear polynomial is $(x - α)$ .

$x^{2} + x + 1 = g (x) (x - α) g (x) = \frac{x^{2} + x + 1}{x - α}$

Find the other linear polynomial by dividing the polynomial $x^{2} + x + 1$ by $x - α$ using long division.

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