Evaluate $ \iint_s (4x \hat i - 2y^2 \hat j + z^2 \hat k)\cdot \hat n ds $ over the curved surface of $x^2 + y^2 = 4$ and $z = 0 \text{ to }z = 3$. Using method $ \iint_s f(x,y(x,z),z)\cdot \frac{\nabla u(x, y)}{|\nabla u(x, y)|} \sqrt{ 1 + \left ( \partial y \over \partial x\right )^2 + \left ( \partial y \over \partial z\right )^2} dxdz$I got $48 \pi - 128.$
EDIT:: added method for above $ \int_0^3 \int_{-2}^2 (4x \hat i - 2y^2 \hat j + z^2 \hat k)\cdot(\hat i x + \hat iy) \left ( \sqrt{ 1 + \frac{x^2}{4 - x^2 } }\right ) dx dz$ $ \implies 12 \int_{-2}^{2} \frac{2x^2}{\sqrt{4 - x^2}} - (4 - x^2)dx = 48 \pi - 128 $ EDIT:: I got wrong answer below because of formula. I got right answer from this! The correct formula should have been $ \iint_s F(\theta, z) \cdot (u_\theta \times u_z) d\theta dz$ Parametrizing $x = 2 \cos \theta, y = 2\sin\theta , z=z $ $ \int_0^3 \int_0^{2\pi} F(\theta, z)\cdot \frac{u_{\theta}\times u_z}{|u_{\theta}\times u_z|}d\theta dz$ I got $24 \pi$. The answer sheet says $48\pi$.Please help!! Thank you!!
surface integral of vector along the curved surface of cylinder
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multivariable-calculus
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0I was asleep, so for a while, it didn't, but it certainly helped you to help yourself! – 2012-06-22
1 Answers
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The quantity $\Phi$ (for flux) you want to compute is given by the formula $\Phi=\int_R {\bf F}\bigl({\bf u}(\theta, z)\bigr) \cdot ({\bf u}_\theta \times {\bf u}_z)\ {\rm d}(\theta ,z)\ ,\qquad R:=[0,2\pi]\times[0,3]\ ,$ which you quote correctly. But in the next line for no reason you divide by $ \bigl|{\bf u}_\theta \times {\bf u}_z\bigr|=2$; therefore your end result is off by a factor of $2$.
As an aside: The orientation of ${\bf n}$ was not defined; so maybe the intended value is $-48\pi$.
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0@Christian Batter Sir can you pls have a look at this problem - https://math.stackexchange.com/questions/2887999/surface-integral-formed-by-paraboloid-of-revolution-and-cylinder?noredirect=1&lq=1 – 2018-08-19