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Chapter 12: Problem 4

Determine whether the given quadratic polynomial is irreducible. [Recall from the text that a quadratic polynomial \(f(x)\) is irreducible if the equation \(f(x)=0\) has no real roots] (a) \(24 x^{2}+x-3\) (b) \(x^{2}+24 x+144\)

Short Answer

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(a) Not irreducible; (b) Not irreducible.

Step by step solution

01

Understand the Definition of Irreducibility for Quadratics

A quadratic polynomial \( ax^2 + bx + c \) is irreducible over the real numbers if it has no real roots. This means its discriminant \( b^2 - 4ac \) is less than zero, as a negative discriminant indicates the roots are non-real complex numbers.
02

Apply the Discriminant Formula for Polynomial (a)

Examine the polynomial \( 24x^2 + x - 3 \). Here \( a = 24 \), \( b = 1 \), and \( c = -3 \). Compute the discriminant using formula \( b^2 - 4ac \):\[ Discriminant = 1^2 - 4 \cdot 24 \cdot (-3) = 1 + 288 = 289 \].Since 289 is positive, the roots are real, and therefore the polynomial is not irreducible.
03

Apply the Discriminant Formula for Polynomial (b)

Examine the polynomial \( x^2 + 24x + 144 \). Here \( a = 1 \), \( b = 24 \), and \( c = 144 \). Compute the discriminant:\[ Discriminant = 24^2 - 4 \cdot 1 \cdot 144 = 576 - 576 = 0 \].Since the discriminant is zero, this polynomial has a repeated real root, and thus it is not irreducible either.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Quadratic Polynomials
Quadratic polynomials are mathematical expressions of the form \( ax^2 + bx + c \), where \( a \), \( b \), and \( c \) are constants, and \( a eq 0 \).
These expressions form a parabola when plotted on a graph, creating a symmetrical curve around its vertex.Quadratic polynomials are essential in algebra because they commonly appear in various mathematical calculations and real-world applications.
They can represent different scenarios such as projectile motion, area optimization, and economics. When determining the properties of a quadratic polynomial, we look at its coefficients and use several methods for analysis.
  • The standard form of a quadratic polynomial: \( ax^2 + bx + c \).
  • Vertex form of a quadratic polynomial: \( a(x - h)^2 + k \), where \((h, k)\) is the vertex.
  • Factored form highlights the roots of the polynomial.
Each form is useful, depending on what information you need to extract from the expression. Identifying roots helps to determine if a polynomial is irreducible over the real numbers.
Discriminant
The discriminant is a specific value calculated from a quadratic's coefficients \( a \), \( b \), and \( c \), and is given by the formula \( b^2 - 4ac \).
The discriminant helps determine the nature of the roots of a quadratic polynomial without actually solving it.The value of the discriminant tells us whether a quadratic has real or non-real roots, and how many of them:
  • If the discriminant is greater than zero, there are two distinct real roots.
  • If the discriminant is zero, there is exactly one real root, also known as a repeated or double root.
  • If the discriminant is less than zero, there are no real roots, meaning the polynomial has complex roots and is irreducible over the real numbers.
In the exercise given, calculating the discriminant for each polynomial helps to determine whether the polynomial is irreducible based on the nature of its roots.
Real Roots
Real roots are the solutions to a polynomial equation that are real numbers. In the context of a quadratic polynomial \( ax^2 + bx + c = 0 \), these are the values of \( x \) for which the equation holds true.
Real roots can be visualized as the points where the polynomial's graph intersects the x-axis.Understanding whether a quadratic has real roots involves exploring its discriminant:
  • If there are two distinct real roots, the graph of the quadratic will intersect the x-axis at two points.
  • If there is a repeated real root, the graph will just touch the x-axis at one point, known as the vertex of the parabola.
Knowing whether a polynomial has real roots is crucial not only for solving equations but also for assessing particular qualities of graphs. Polynomials determined to be irreducible lack real roots, graphically indicating no intersection with the x-axis and confirming their irreducibility over the real plane.

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Most popular questions from this chapter

Determine a quadratic equation with the given roots: (a) \(a / b,-b / a\) (b) \(-a+2 \sqrt{2 b},-a-2 \sqrt{2 b}\)

You are given an improper rational expression. First, use long division to rewrite the expression in the form (polynomial) \(+\) (proper rational expression) Next, obtain the partial fraction decomposition for the proper rational expression. Finally, rewrite the given improper rational expression in the form (polynomial) \(+\) (partial fractions) \frac{6 x^{3}-16 x^{2}-13 x+25}{x^{2}-4 x+3}

The following result is a particular case of a theorem proved by Professor David C. Kurtz in The American Mathematical Monthly [vol. \(99(1992), \text { pp. } 259-263]\) Suppose we have a cubic equation \(a_{3} x^{3}+a_{2} x^{2}+a_{1} x+a_{0}=0\) in which all of the coefficients are positive real numbers. Furthermore, suppose that the following two inequalities hold. $$ a_{1}^{2}>4 a_{0} a_{2} \quad \text { and } \quad a_{2}^{2}>4 a_{1} a_{3} $$ Then the cubic equation has three distinct real roots. (a) Check that these inequalities are valid in the case of the equation \(2 x^{3}+8 x^{2}+7 x+1=0 .\) This implies that the equation has three distinct real roots. Use a graphing utility to verify this and to estimate each root to the nearest one hundredth. (b) Follow part (a) for the equation \(3 x^{3}+40 x^{2}+100 x+30=0\) (c) Use a graphing utility to demonstrate that the graph of \(y=6 x^{3}+15 x^{2}+11 x+2\) has three distinct \(x\) -intercepts. Thus, the equation \(6 x^{3}+15 x^{2}+11 x+2=0\) has three distinct real roots. Now check that the condition \(a_{2}^{2}>4 a_{1} a_{3}\) fails to hold in this case. Explain why this does not contradict the result from Professor Kurtz stated above.

First graph the two functions. Then use the method of successive approximations to locate, between successive thousandths, the \(x\)-coordinate of the point where the graphs intersect.Use a graphing utility to draw the graphs as well as to check your final answer. $$y=x^{5}+100 ; y=x^{5}+\frac{1}{2} x^{3}$$

Determine the partial fraction decomposition for each of the given rational expressions. Hint: In Exercises \(17,18,\) and \(26,\) use the rational roots theorem to factor the denominator. $$\frac{x^{3}+2}{x^{4}-8 x^{2}+16}$$
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