Application of derivative: 4m long ladder leans against the wall and being pulled horizontally....

[KamCh]

Hey guys, had a test today with a derivative application question. Can you please tell me if I got it right.

4m long ladder leans against the wall and being pulled horizontally away from the wall at the rate of 0.5 m/s. How fast area of right triangle changes when top of the ladder is 1m above the ground? Sorry for bad image quality.

 

[Harry_the_cat]

I cant read your final answer. Can you type it out please?

 

[MarkFL]

I can't make heads nor tails out of the image you uploaded. I would let \(x\) be the horizontal distance of the bottom of the ladder from the wall and \(y\) be the vertical distance along the wall the top of the ladder is above the ground. Both are measured in meters. And so the area of the triangle formed by the ladder, wall and ground is:

[MATH]A=\frac{1}{2}xy[/MATH]
Differentiating with respect to time \(t\) (in seconds), we obtain:

[MATH]\d{A}{t}=\frac{1}{2}\left(\d{x}{t}y+x\d{y}{t}\right)[/MATH]
Now, we know by the theorem of Pythagoras:

[MATH]x^2+y^2=4^2\implies x^2=4^2-y^2[/MATH]
Differentiating with respect to time:

[MATH]2x\d{x}{t}+2y\d{y}{t}=0\implies \d{y}{t}=-\frac{x}{y}\d{x}{t}[/MATH]
And so we have:

[MATH]\d{A}{t}=\frac{1}{2}\d{x}{t}\left(y-\frac{4^2-y^2}{y}\right)=\frac{1}{y}\d{x}{t}\left(y^2-8\right)[/MATH]
Plugging in the given data (\(y=1,\,\d{x}{t}=\frac{1}{2}\)), we find:

[MATH]\d{A}{t}=\frac{1}{1}\cdot\frac{1}{2}\left(1^2-8\right)=-\frac{7}{2}\,\frac{\text{m}^2}{\text{s}}[/MATH]
Is that the result you obtained?

 

[KamCh]

I cant read your final answer. Can you type it out please?

-7/2 m^2 / s

 

[KamCh]

I can't make heads nor tails out of the image you uploaded. I would let \(x\) be the horizontal distance of the bottom of the ladder from the wall and \(y\) be the vertical distance along the wall the top of the ladder is above the ground. Both are measured in meters. And so the area of the triangle formed by the ladder, wall and ground is:

[MATH]A=\frac{1}{2}xy[/MATH]
Differentiating with respect to time \(t\) (in seconds), we obtain:

[MATH]\d{A}{t}=\frac{1}{2}\left(\d{x}{t}y+x\d{y}{t}\right)[/MATH]
Now, we know by the theorem of Pythagoras:

[MATH]x^2+y^2=4^2\implies x^2=4^2-y^2[/MATH]
Differentiating with respect to time:

[MATH]2x\d{x}{t}+2y\d{y}{t}=0\implies \d{y}{t}=-\frac{x}{y}\d{x}{t}[/MATH]
And so we have:

[MATH]\d{A}{t}=\frac{1}{2}\d{x}{t}\left(y-\frac{4^2-y^2}{y}\right)=\frac{1}{y^2}\d{x}{t}\left(y^2-8\right)[/MATH]
Plugging in the given data (\(y=1,\,\d{x}{t}=\frac{1}{2}\)), we find:

[MATH]\d{A}{t}=\frac{1}{1^2}\cdot\frac{1}{2}\left(1^2-8\right)=-\frac{7}{2}\,\frac{\text{m}^2}{\text{s}}[/MATH]
Is that the result you obtained?

Thank you so much!

 

[MarkFL]

Thank you so much!

I made a minor error, but it didn't affect the numerical result. I should have obtained:

[MATH]\d{A}{t}=\frac{1}{y}\d{x}{t}\left(y^2-8\right)[/MATH]
I previously had \(y^2\) in the denominator of the first factor on the RHS. Sorry for the confusion.

 

[Harry_the_cat]

-7/2 m^2 / s

Yes I agree with that too.