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Chapter 4: Problem 92

If the ratio of the roots of \(a_{1} x^{2}+b_{1} x+c_{1}=0\) be equal to the ratio of the roots of \(a_{2} x^{2}+b_{2} x+c_{2}=0\), then \(\frac{a_{1}}{a_{2}}\), \(\frac{b_{1}}{b_{2}}, \frac{c_{1}}{c_{2}}\) are in (A) A.P. (B) G.P. (C) H.P. (D) None of these

Short Answer

Expert verified
The ratios form a Geometric Progression (B).

Step by step solution

01

Understand the problem

We need to find the relationship between the coefficients of two quadratic equations where the ratio of their roots are equal.
02

Recall the quadratic formula

The roots of a quadratic equation \(ax^2 + bx + c = 0\) are given by \(\frac{-b \pm \sqrt{b^2 - 4ac}}{2a}\).
03

Express the ratio of roots for both equations

For the equation \(a_{1}x^{2}+b_{1}x+c_{1}=0\), let the roots be \(r_1\) and \(r_2\). The ratio of the roots of the first equation is \( \frac{r_1}{r_2} = \frac{-b_{1} + \sqrt{b_{1}^2 - 4a_{1}c_{1}}}{-b_{1} - \sqrt{b_{1}^2 - 4a_{1}c_{1}}} \). Similarly, find the ratio for the second equation.
04

Equate the ratios of roots

Since the ratios of the roots are given to be equal, set the expression for the first ratio equal to the expression for the second: \[ \frac{-b_{1} + \sqrt{b_{1}^2 - 4a_{1}c_{1}}}{-b_{1} - \sqrt{b_{1}^2 - 4a_{1}c_{1}}} = \frac{-b_{2} + \sqrt{b_{2}^2 - 4a_{2}c_{2}}}{-b_{2} - \sqrt{b_{2}^2 - 4a_{2}c_{2}}} \]
05

Simplify the equation

Simplify each side of the equation to get a potential expression with the coefficients. The simplification will show that both expressions are equal when the ratios \( \frac{a_{1}}{a_{2}} = \frac{b_{1}}{b_{2}} = \frac{c_{1}}{c_{2}} \) exist.
06

Identify the sequence type

When \( \frac{a_{1}}{a_{2}} = \frac{b_{1}}{b_{2}} = \frac{c_{1}}{c_{2}} \), it means that these ratios are constant. A constant sequence is an example of a Geometric Progression (G.P.), where every element is the same constant.

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Key Concepts

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

Roots of Quadratic Equations
Quadratic equations are fundamental in algebra and take the form \( ax^2 + bx + c = 0 \). These equations have up to two solutions or roots, which can be real or complex numbers. Understanding the nature of these roots is essential because they reveal important properties about the graph of the equation—a parabola. The roots of a quadratic equation are determined using the quadratic formula: \[ x = \frac{-b \pm \sqrt{b^2 - 4ac}}{2a} \] Here, the expression \( b^2 - 4ac \) is known as the discriminant. It tells you whether the roots are real or complex:
  • If the discriminant is greater than zero, the equation has two distinct real roots.
  • If it is zero, the equation has exactly one real root (also known as a repeated or double root).
  • If less than zero, the roots are complex numbers.
Understanding how to find and interpret these roots is crucial for solving problems involving quadratic equations.
Ratios in Algebra
Algebra often involves working with ratios, which are comparisons between two quantities. In the context of quadratic equations, you might encounter ratios when comparing coefficients or roots of similar equations. The ratio of two numbers \( a \) and \( b \) is expressed as \( \frac{a}{b} \). When applied to the roots of quadratic equations, ratios provide a meaningful way to compare different equations, especially when investigating their similarities or analyzing their behavior. In the given problem, you are comparing the ratios of the roots from two different quadratic equations. The key is to express each pair of roots and set their ratios equal, leading to useful relationships between the coefficients of the equations. When these ratios among roots are equal for two different equations, it highlights a deeper mathematical relationship that can solve the problem.
Geometric Progression
A geometric progression (G.P.) is a sequence of numbers where each term after the first is found by multiplying the previous one by a constant called the common ratio. For example, in the sequence \( 2, 4, 8, 16, \ldots \), the common ratio is 2. This pattern continues indefinitely. Geometric progressions can describe many natural phenomena where growth or decay happens at a constant rate. In the given problem, the coefficients \( \frac{a_{1}}{a_{2}}, \frac{b_{1}}{b_{2}}, \frac{c_{1}}{c_{2}} \) form a G.P. This happens because when the ratios of the roots of two quadratic equations are equal, the relationship between their coefficients also follows a consistent and uniform pattern. Understanding geometric progressions helps in solving problems like these, where relationships between multiple terms are involved. By recognizing the pattern, you can simplify complex algebraic concepts into more accessible forms.

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Most popular questions from this chapter

If \(b>a\), then the equation \((x-a)(x-b)-1=0\) has (A) both roots in \((-\infty, a)\) (B) one root in \((-\infty, a)\) and other in \((b, \infty)\) (C) both roots in \((b, \infty)\) (D) both roots in \([a, b]\)

Let \(k\) be any point such that \(k \in R\) and \(\alpha, \beta\) are the roots of the quadratic equation \(f(x)=a x^{2}+b x+c=0\). If \(k\) lies outside and is less than both the roots then the equation must have real and distinct roots and the sign of \(f(k)\) is same as the sign of ' \(a\) '. Also, \(k\) is less than the \(x\)-coordinate of the vertex of the parabola \(y=a x^{2}+b x+c\). If \(k\) lies between both the roots, then the sign of \(f(k)\) is opposite to the sign of ' \(a\) '. If \(k\) lies outside and is greater than both the roots, then the sign of \(f(k)\) is same as the sign of ' \(a\) '. Also, \(k\) is greater than the \(x\)-coordinate of the vertex of the parabola \(y=a x^{2}+b x+c\). If both the roots of the equation lie between two real numbers \(k_{1}\) and \(k_{2}\), then equation must have real and distinct roots and the sign of \(f\left(k_{1}\right)\) and \(f\left(k_{2}\right)\) is same as the sign of \(a\). Also, the \(x\)-coordinate of the vertex of the parabola \(y=a x^{2}+b x+c\) lies between \(k_{1}\) and \(k_{2}\). The values of ' \(a\) ' so that 6 lies between the roots of the equation \(x^{2}+2(a-3) x+9=0\), are (A) \(a>-\frac{3}{4}\) (B) \(a<-\frac{3}{4}\) (C) \(a>\frac{3}{4}\) (D) \(a<\frac{3}{4}\)

The quadratic equations \(x^{2}-6 x+a=0\) and \(x^{2}-c x+\) \(6=0\) have one root in common. The other roots of the first and second equations are integers in the ratio \(4: 3 .\) Then the common root is (A) 1 (B) 4 (C) 3 (D) 2

If \(p x^{2}+q x+r=0\) has no real roots and \(p, q, r\) are real such that \(p+r>0\), then (A) \(p-q+r \leq 0\) (B) \(p+r \geq q\) (C) \(p+r=q\) (D) None of these

If \(x_{1}, x_{2}, x_{3}, \ldots, x_{n}\) are the roots of the equation \(x^{n}+a x+\) \(b=0\), then the value of \(\left(x_{1}-x_{2}\right)\left(x_{1}-x_{3}\right)\left(x_{1}-x_{4}\right) \ldots\) \(\left(x_{1}-x_{n}\right)\) is equal to (A) \(n x_{1}^{n-1}+a\) (B) \(n\left(x_{1}\right)^{n-1}\) (C) \(n x_{1}+b\) (D) \(n x_{1}^{n-1}+b\)
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