Answer:
The top of the ladder is sliding down at a rate of 2 feet per second.
Step-by-step explanation:
Refer the image for the diagram. Consider [tex]\Delta ABC[/tex] as right angle triangle. Values of length of one side and hypotenuse is given. Value of another side is not known. So applying Pythagoras theorem,
[tex] \left ( AB \right )^{2}+\left ( BC \right )^{2}=\left ( AC \right )^{2}[/tex]
From the given data, [tex] L=15\:ft=AC[/tex], [tex] y=9\:ft=AB[/tex] and [tex] x=BC[/tex]
Substituting the values,
[tex] \therefore \left ( 9 \right )^{2}+\left ( x \right )^{2}=\left ( 15 \right )^{2}[/tex]
[tex] \therefore 81+x^{2}=225[/tex]
[tex] \therefore x^{2}=225-81[/tex]
[tex] \therefore x^{2}=144[/tex]
[tex] \therefore \sqrt{x^{2}}=\sqrt{144} [/tex]
[tex] \therefore x=\pm 12 [/tex]
Since length can never be negative, so [tex] x= 12 [/tex].
Now to calculate [tex] \dfrac{dy}{dt}[/tex] again consider following equation,
[tex] \left ( y \right )^{2}+\left ( x \right )^{2}=\left ( l \right )^{2}[/tex]
Differentiate both sides of the equation with respect to t,
[tex] \dfrac{d}{dt}\left(y^2+x^2\right)=\dfrac{d}{dt}\left(l^2\right)[/tex]
Applying sum rule of derivative,
[tex] \dfrac{d}{dt}\left(y^2\right)+\dfrac{d}{dt}\left(x^2\right)=\dfrac{d}{dt}\left(l^2\right)[/tex]
[tex] \dfrac{d}{dt}\left(y^2\right)+\dfrac{d}{dt}\left(x^2\right)=\dfrac{d}{dt}\left(225\right)[/tex]
Applying power rule of derivative,
[tex] 2y\dfrac{dy}{dt}+2x\dfrac{dx}{dt}=0[/tex]
Simplifying,
[tex] y\dfrac{dy}{dt}+x\dfrac{dx}{dt}=0[/tex]
Substituting the values,
[tex] 9\dfrac{dy}{dt}+12\times1.5=0[/tex]
[tex] 9\dfrac{dy}{dt}+18=0[/tex]
Subtracting both sides by 18,
[tex] 9\dfrac{dy}{dt}=-18 [/tex]
Dividing both sides by 9,
[tex] \dfrac{dy}{dt}= - 2 [/tex]
Here, negative indicates that the ladder is sliding in downward direction.
[tex]\therefore \dfrac{dy}{dt}= 2\:\dfrac{ft}{sec}[/tex]
