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Let $C_1$ be a fixed circumference with equation $(x-1)^2 + y^2 = 1$ and $C_2$ a circumference to be shrinked, with center at $(0, 0)$ and radius $r$.

Let $P$ be the point $(0, r)$, $Q$ the upper intersection between $C_1$ and $C_2$ and $R$ the intersection between the line $PQ$ with the $x$ axis.

What happens with $R$ when $C_2$ shrinks (i.e., $r \rightarrow 0^+$) ?

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Since I cannot think of anything clever, I will compute. The answer turns out to be different from what geometric intuition might suggest.

The point $P=P(r)$ has coordinates $(0,r)$. We find the coordinates of $Q$. So we are solving the system $(x-1)^2+y^2=1,\qquad x^2+y^2=r^2.$ Subtract. We get $2x=r^2$, so $x=r^2/2$. The $y$-coordinate of the upper point of intersection is therefore $\sqrt{r^2-r^4/4}$. Now we find the equation of the line $PQ$. In the usual way we obtain the equation $\frac{y-r}{x}=\frac{\sqrt{r^2-r^4/4} -r}{r^2/2}.$ The $x$-intercept is obtained by putting $y=0$. We get $x=\frac{-r^3/2}{\sqrt{r^2-r^4/4}-r}.$ Now it is time to take the limit. We can simplify our expression slightly to $x= \frac{r^2/2}{1-\sqrt{1-r^2/4}}.$ The taking of the limit is routine. We can for example multiply top and bottom by $1+\sqrt{1-r^2/4}$. Or recall more informally that if $\epsilon$ is small, $\sqrt{1-\epsilon}\approx 1-\epsilon/2$. Either way, the limit turns out to be $4$. Surprise!

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    Yeah, this problem is intriguing. It would be nice to see a zoomed image showing that it's really 4, but i don't know if that is possible.2012-04-07
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The upper intersection point $T=(a,b)$ is on both $C_1$ and $C_2$ and has positive $y$-component. Thus

$\begin{cases}a^2+b^2=r^2 \\ (a-1)^2+b^2=1. \end{cases}$

Subtracting the first from the second, we obtain $1-2a=1-r^2$, and thus $a=r^2/2$. We can then solve for $b$ as $b=\sqrt{r^2-(r^2/2)^2}=r\sqrt{1-(r/2)^2}$. Therefore $T=\left(r^2/2,r\sqrt{1-(r/2)^2}\right)$. The line going between $T$ and $(0,r)$ is given by

$\frac{y-r}{x-0}=\frac{b-r}{a-0}=\frac{r\sqrt{1-(r/2)^2}-r}{r^2/2-0}.$

The $x$-intercept occurs when we set $y=0$; solving for $x$ gives us

$x=\frac{-r(r^2/2)}{r\sqrt{1-(r/2)^2}-r} \cdot \frac{1+\sqrt{1-(r/2)^2}}{1+\sqrt{1-(r/2)^2}}=2\left(1+\sqrt{1-(r/2)^2}\right).$

Clearly as $r\to0$, $x\to 4$.