- #1
Nono713
Gold Member
MHB
- 618
- 4
Here's a nice geometry problem, not hard at all if you can see what's really going on.
https://lh3.googleusercontent.com/-qqF-3y81rvI/UQjt7jishKI/AAAAAAAAAII/gP8G0dgKCmc/w497-h373/cercles.gif
Solution (don't click if you want to work it out yourself!):
https://lh3.googleusercontent.com/-qqF-3y81rvI/UQjt7jishKI/AAAAAAAAAII/gP8G0dgKCmc/w497-h373/cercles.gif
Solution (don't click if you want to work it out yourself!):
Let M be the midpoint of [AB]. Then (OM) is perpendicular to (AB). We know |OA|, so by Pythagoras we have:
$$|OA|^2 = |OM|^2 + |AM|^2 = |OM|^2 + \left ( \frac{1}{2} |AB| \right )^2$$
Because the inner circle is tangent to (AB) at M (as $|OA| = |OB|$) its area is:
$$A_\text{inner} = \pi |OM|^2 = \pi \left [ |OA|^2 - \left ( \frac{1}{2} |AB| \right )^2 \right ]$$
And the area of the outer circle is just:
$$A_\text{outer} = \pi |OA|^2$$
Thus the area of the shaded region is:
$$A_\text{shaded} = A_\text{outer} - A_\text{inner} = \pi |OA|^2 - \pi \left [ |OA|^2 - \left ( \frac{1}{2} |AB| \right )^2 \right ] = \pi \left ( \frac{1}{2} |AB|\right )^2 = \frac{\pi}{4} |AB|^2$$
The maximum value for $|AB|$ is clearly $2 |OA|$ when [AB] is a diameter of the circumcircle, thus $A_\text{shaded} \leqslant A_\text{outer}$.
$$|OA|^2 = |OM|^2 + |AM|^2 = |OM|^2 + \left ( \frac{1}{2} |AB| \right )^2$$
Because the inner circle is tangent to (AB) at M (as $|OA| = |OB|$) its area is:
$$A_\text{inner} = \pi |OM|^2 = \pi \left [ |OA|^2 - \left ( \frac{1}{2} |AB| \right )^2 \right ]$$
And the area of the outer circle is just:
$$A_\text{outer} = \pi |OA|^2$$
Thus the area of the shaded region is:
$$A_\text{shaded} = A_\text{outer} - A_\text{inner} = \pi |OA|^2 - \pi \left [ |OA|^2 - \left ( \frac{1}{2} |AB| \right )^2 \right ] = \pi \left ( \frac{1}{2} |AB|\right )^2 = \frac{\pi}{4} |AB|^2$$
The maximum value for $|AB|$ is clearly $2 |OA|$ when [AB] is a diameter of the circumcircle, thus $A_\text{shaded} \leqslant A_\text{outer}$.