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If the ratio of roots of $ax^2+bx+c = 0\space$and $px^2+qx+r = 0\space$is same. How to find ratio of their discriminants?

I don't understand this problem,what exactly is meant by ratio of the roots being same?

Let, $\alpha, \beta$ and $\gamma,\delta$ are the roots of the two equations respectively,does this problem says that $\frac{\alpha}{\beta} = \frac{\gamma}{\delta}=k$, where $k \in \mathbb{Q}$?

Even so I am not really much ideas how to continue without messing with tedious algebraic manipulation,again,considering this problem is of quantitative aptitude category,it may not be the right approach.Any ideas?

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    @Arturo Magidin:Aha,thanks :) you are right,I missed it completely by assuming the coefficients lie in $\mathbb{Q}$.However,for the rest,would you advice using the quadratic formula and then manipulating things?2011-10-12

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The ratio of the roots of the first quadratic polynomial are $(|b|-\sqrt{b^2-4ac})/(|b|+\sqrt{b^2-4ac})$. This is a one-to-one function of $ac/b^2$ hence the ratios coincide for the two polynomials if and only if $ac\cdot q^2=pr\cdot b^2$ $(*)$.

The discriminants of the quadratic forms are $D=b^2-4ac$ and $\Delta=q^2-4pr$ hence $(*)$ is equivalent to the condition that $b^2\cdot\Delta=q^2\cdot D$.

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    You know that $u(x)=u(y)$ and you want to deduce that $x=y$. This is not true in general (consider $u(x)=x^2$ on the real line) but [this holds for one-to-one functions](http://en.wikipedia.org/wiki/Injective_function#Definition).2011-10-12
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you can use Vieta's formulas :

$x_1+x_2=\frac{-b}{a}$ ,and $x_1x_2=\frac{c}{a}$ ,so we may write following:

$x_1^2+2x_1x_2+x_2^2=\frac{b^2}{a^2}$ , if we devide this equation by $x_1x_2$ we get

$\frac{x_1}{x_2}+\frac{x_2}{x_1}+2=\frac{b^2}{ac} \Rightarrow\frac{x_1}{x_2}+\frac{x_2}{x_1}-2=\frac{\Delta_1}{ac} \Rightarrow k+\frac{1}{k}-2=\frac{\Delta_1}{ac}$

Similarly we can show that $k+\frac{1}{k}-2=\frac{\Delta_2}{pr}$ ,so if you devide these last two equations you get:

$\frac{\Delta_1}{\Delta_2}=\frac{ac}{pr}$

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    $\frac{\Delta_1}{\Delta_2}=\frac{\Delta_1+4ac}{\Delta_2+4pr}$2011-10-12
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let equations be $ax^2+bx+c=0$ and $px^2+qx+r=0$ let roots of $ax^2+bx+c=0$ be $m$ and $n$ let roots of $px^2+qx+r=0$ be $l$ and $o$ then ${m\over n}={l\over o}$ by componendo and dividendo law ${m+n\over m-n} ={l+o\over l-o}$ by solving them we get ${b^2-4ac\over q^2-4pr}={b^2\over q^2}$

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    Please use Mathjax to make your answers more readable2016-07-01