Let AF be the altitude from A to BE
Let M be the midpoint of CD (lies on AF)
∆ACD has 1/4 the area of ∆ABE
so, since ACD ~ ABE, CD = 1/2 BE and AM = 1/2 AF
BE*AF/2 = 100
BE=200/20 = 10
so, CD = 5
Let M be the midpoint of CD (lies on AF)
∆ACD has 1/4 the area of ∆ABE
so, since ACD ~ ABE, CD = 1/2 BE and AM = 1/2 AF
BE*AF/2 = 100
BE=200/20 = 10
so, CD = 5
Let's start by drawing a diagram to better understand the problem. Assume $AB$ is the base of the isosceles triangle and $AE$ is the altitude from $A$.
We know that the area of triangle $ABE$ is $100$ square inches, and the altitude from $A$ is $20$ inches. Hence, the length of base $AB$ is $\frac{2 \times \text{Area}}{\text{Base}} = \frac{2 \times 100}{20} = 10$ inches.
Now, consider triangle $ABE$ divided by line $\overline{CD}$. Let $M$ be the midpoint of $\overline{AB}$.
As triangle $ABE$ is isosceles, we can conclude that $\overline{AM} = \overline{BM}$.
Let $x$ represent the length of $\overline{CD}$. Since triangles $ADM$ and $BMC$ are similar, we can set up the following proportion:
$$\frac{\text{Base of } ADM}{\text{Base of } BMC} = \frac{\text{Altitude of } ADM}{\text{Altitude of } BMC}$$
The base of triangle $ADM$ is $10 - x$, the base of triangle $BMC$ is $x$, and the altitudes are $20$ (given). So, we have:
$$\frac{10 - x}{x} = \frac{20}{20} = 1$$
Simplifying the equation, we get:
$$10 - x = x$$
$$10 = 2x$$
$$x = \frac{10}{2}$$
$$x = 5$$
Therefore, the length of $\overline{CD}$ is $5$ inches.