The answer is $|\frac rp -7|\ge 4\sqrt 3$
Since they are in AP $$2q=p+r$$ For x to be real $$q^2-4pr\ge 0$$ Then $$(\frac{p+r}{2})^2-4pr\ge 0$$ $$p^2+r^2-14pr\ge 0$$ I don’t know that to do next. Please help.
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@stevengregory which is strange, given that $14= 2\times 7$ and $7$ is part of the answer. $p^2+r^2-14pr\ge 0$ looks good to me – Henry Sep 10 '19 at 15:43
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Next divide through by $p^2$, complete the square and take square roots:
$$p^2+r^2-14pr\ge 0$$ $$\left(\frac rp\right)^2 - 14 \frac rp \ge -1$$ $$\left(\frac rp\right)^2 - 14 \frac rp +49 \ge 48$$ $$\left(\frac rp-7\right)^2 \ge 48$$ $$\left|\frac rp-7\right| \ge \sqrt{48}$$ $$\left|\frac rp-7\right| \ge 4\sqrt{3}$$
Henry
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Hint Divide both sides of the equation by $p^2$ to produce a polynomial in $\frac{r}{p}$ and then complete the square.
Travis Willse
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