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I have quoted the question. This assignment is past due and I have questions about the solution:

Computer the path integral of $\int_C{f} \, ds $ where $f(x,y,z)= x^2$ and the path C is the intersection of the sphere $x^2+y^2+z^2=1$ and the plane $x+y+z = 0$.

So the way I see it is that the intersection of the sphere and curve gives us a circle on the xy plane with radius one. So i thought the parametrization is as simple as $x = cos(t)$ and $y=sin(t)$ but it's not. Here is the correct solution.

http://imgur.com/Mcrsq

How is it that they are parametrizing using vectors. What is the reasoning/logic behind it?

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    $x^2$+$y^2$+$z^2$ equals what? I am confused by the equation of the sphere.2011-11-12
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    sorry, it equals one. I will edit.2011-11-12
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    Have you considered spherical coordinates?2011-11-12
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    The circle is not in the x-y plane. The plane contains the point $(1,1,−2)$, e.g. So the circle contains the point ${1\over \sqrt6}(1,1,-2)$.2011-11-12
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    even so, shouldnt the parametrization be the same?2011-11-12
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    No, your parameterization gives the unit circle in the $x$-$y$ plane. A parameterization of a curve would give the location of a point moving along the curve at time $t$. Different curves have different parameterizations.2011-11-12
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    Because the path is defined by two equations symmetric under all permutations of $\{x,y,z\}$, it follows $\int_C f ds$ = $\int_C x^2 ds$ = $\int_C y^2 ds$ = $\int_C z^2 ds$. Therefore $\int_C f dx$ = $\frac{1}{3}\int_C (x^2+y^2+z^2)ds$ = $\frac{1}{3}\int_c 1 ds$ = length of the path/3, which--because the plane passes through the center of the sphere--must equal $2\pi/3$.2011-11-12
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    oh wow whuber, awesome. thanks for that. And thanks David, I understand it now.2011-11-12

1 Answers 1

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Looking at the solution provided in your link, you're asking "how do I parameterize a circle in $\Bbb R^3$".

If the circle has radius $r$, is centered at the origin, and contains the points $p_1=(x_1,y_1,z_1)$ and $p_2=(x_2,y_2,z_2)$ which, when thought of as vectors, have norm one and are orthogonal, a vector parameterization is ${\bf x}(t)= r p_1 \cos t +r p_2\sin t. $


To see that this gives a circle:

Any linear combination of $p_1$ and $p_2$ (thinking of them as vectors) lies in the plane determined by $p_1$ and $p_2$. Using the fact that $p_1$ and $p_2$ are orthogonal, it follows that $r p_1 \cos t + r p_2\sin t$ has norm r. Indeed $$ || r p_1 \cos t +r p_2\sin t||^2= r^2\cos^2 t ||p_1||^2+ r^2\sin^2 t ||p_2||^2=r^2(\cos^2t+\sin^2t)=r^2 $$

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    thanks. I guess my answer was "close enough" that it was specific to xy plane and the unit circle. However now that we are not in the xy plane (but still have a unit circle in the plane) we get a different parametrization.2011-11-12