The length of a segment with endpoints in (x1, y1) and (x2, y2) is calculated as:
[tex]\sqrt[]{(x_2-x_1)^2+(y_2-y_1)^2}[/tex]Then, the distance from E(7,9) to R(1,1) is:
[tex]\sqrt[]{(1-7)^2+(1-9)^2}=\sqrt[]{(-6)^2+(-8)^2}=\sqrt[]{100}=10[/tex]At the same way, the distance from E(7,9) to D(15,3) is:
[tex]\sqrt[]{(15-7)^2+(3-9)^2}=\sqrt[]{8^2+(-6)^2}=\sqrt[]{100}=10[/tex]Therefore ER has a length of 10 ft and ED has a length of 10 ft, So the area of the triangle is calculated as:
[tex]\text{Area}=\frac{ER\cdot ED}{2}=\frac{10\cdot10}{2}=50ft^2[/tex]Because ER and ED are the base and the height of the right triangle
Now, we need to transform 50 square feet into square inches as:
[tex]50ft^2=50ft^2\cdot\frac{144in^2}{1ft^2}=7200in^2[/tex]Now, the minimum number of stones required is calculated as:
[tex]\frac{7200in^2}{29.26in^2}=246.069\approx247[/tex]Because every stone cover 29.26 square inches
Finally, the total cost of the stones is:
247 * $0.42 = $103.74
Because every stone has a cost of $0.42
Answers: 1. 10 ft
2. 10 ft
3. 50 ft^2 = 7200 in^2
4. 247
5. $103.74
