The maximum distance from Earth to the sun is $9.3\times10^7$ miles. The minimum distance is $9.1\times10^7$ miles. The sun is at one focus of the elliptical orbit. Find the distance from the sun to the other focus.
I tried to solve this using logic; I don't know if this works or if there is a mathematical solution.
My interpretation:
If this interpretation is correct then the distance from the sun to the other focus will be $0.2\times10^7$ or $2\times10^6$.
Is this correct? If not, what is the correct interpretation?
Using the geometry of ellipses, each focus point is displaced by $\epsilon a$ from the center where $\epsilon$ is the eccentricity of the ellipse and $a$ is the semimajor axis. The perihelion of an ellipse is given by $a(1-\epsilon)$ and the aphelion is given by $a(1+\epsilon)$. So you know that $$a(1-\epsilon)=9.1\times10^7\text{ miles}$$ $$a(1+\epsilon)=9.3\times10^7\text{ miles}$$ and you're looking for the distance between foci which will be $2\epsilon a$. Solving this system of equations I get that $2\epsilon a= 2.0 \times 10^6\text{ miles}$ so your answer looks good.
Another way to do this without all the ellipse properties it to notice that the total width of the ellipse is $18.4 \times10^7\text{ miles}$ so the center is located a distance of $9.2 \times 10^7\text{ miles}$ away from the left hand side and therefore the distance from the center of the ellipse to one foci is $1.0\times10^6\text{ miles}$ which you can multiply by $2$ to get the result.