I have 2 questions I would like assistance with.
1) Find the area of the region bounded by the graphs $y=5x, y=15x, y=\frac{4}{x}, y=\frac{8}{x}$
This was very difficult and tedious.
I had trouble jotting it down so i drew it using a computer program, and if I understood the question correctly, we are required to find the area that i marked with a circle in this picture https://fbcdn-sphotos-h-a.akamaihd.net/hphotos-ak-prn2/v/t35.0-12/10360308_10152462327944628_1787541395_o.jpg?oh=8f0647c808a4e0cbfad86286492e792f&oe=53787F81&gda=1400376869_ad976f8063efd7f49d8eb9b1ee9a894d
I will spare you my entire calculations, it was easily over 3 pages long, basically since I have no easy way of finding this integral, i first found the area of small region yellow blue and green, then I drew a line paralel to x axis from the point of convergence of red and yellow, found the area of the region bound between red, blue, and the paralel line we drew.
Then I found the area of the entire triangle, and subtracted the areas we found before. that why i isolated the area requested and my final answer is $\frac{2\sqrt{30}}{15}-4\sqrt{12}+4\sqrt{60}-8-log(9) \approx 12.0549$
Now just multiply by 2 to get the answer for both circles.
There has to be an easier way. I'd like to compare answers with someone more knowledgable.
2) Find the area of the region bound inside the loop $(x+y)^3 =axy$ , $a >0$ in the first quadrant.
Hint: Use the transform $x=rcos^2 \theta$, $y=rsin^2 \theta$
What I did:
Basically I just want to make sure I got the limits right.
if we do the transform suggested, we get $r^3 =ar^2 cos^2\theta sin^2 \theta$
divide by $r^2$ to get $r=acos^2 \theta sin^2 \theta$ so $r$ varies from $0$ to $a\cos^2\theta sin^2 \theta$
How can we know how $\theta$ varies?
Answer
For the first problem, change variables to $u=\frac{y}{x}$ and $v=xy$. Then you want to integrate over the region with $(u,v)\in[5,15]\times[4,8]$. By the Change of Variables Theorem, $$\int_{\phi(S)}f(x,y)\,dxdy=\int_Sf(u,v)\,|\det D\phi|\,dudv$$
where $D\phi$ is the Jacobi matrix of the mapping $$\phi(u,v)=\langle \underbrace{v^{1/2}u^{-1/2}}_{=x},\underbrace{v^{1/2}u^{1/2}}_{=y}\rangle$$
(Note that this will only yield the region in the first quadrant, because $x$ and $y$ are positive. To compute the inverse $\phi$, you have to separate the two regions, but they will have the same area by symmetry.) The Jacobi matrix is $$D\phi=\begin{pmatrix}\frac{\partial x}{\partial u} & \frac{\partial x}{\partial v}\\\frac{\partial y}{\partial u} & \frac{\partial y}{\partial v}\end{pmatrix}=\begin{pmatrix}-\frac{1}{2}v^{1/2}u^{-3/2} & \frac{1}{2}v^{-1/2}u^{-1/2} \\ \frac{1}{2}v^{1/2}u^{-1/2} & \frac{1}{2}u^{1/2}v^{-1/2}\end{pmatrix}$$
The determinant of this matrix is $$-\frac{1}{4}u^{-1}-\frac{1}{4}u^{-1}=-\frac{1}{2u}$$
Since $u>0$ in our region of integration, the absolute value of this determinant is $\frac{1}{2u}$. So our integral is $$\int_4^{8}\int_5^{15}\frac{1}{2u}\,dudv=\frac{1}{2}\cdot 4\ln3=2\ln 3=\ln 9$$
You have to double this if you want to include the region in the third quadrant.
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