Double integral with transformation

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SUMMARY

The discussion focuses on solving the double integral \(\int\int x^2 dA\) over the area defined by the ellipse \(5x^2 + 4xy + y^2 = 1\). Participants suggest using a transformation to convert the ellipse into a circle for easier integration. The recommended approach involves diagonalizing the associated matrix \(\mathsf{A}\) and defining new coordinates \(x'\) and \(y'\) aligned with the ellipse's axes. This transformation simplifies the integral by allowing the use of polar coordinates after finding the Jacobian for the variable change.

PREREQUISITES
  • Understanding of double integrals and their applications
  • Familiarity with coordinate transformations, specifically from elliptical to circular coordinates
  • Knowledge of linear algebra concepts, including eigenvalues and matrix diagonalization
  • Ability to compute the Jacobian for variable changes in integrals
NEXT STEPS
  • Study the process of diagonalizing matrices in linear algebra
  • Learn how to compute the Jacobian for transformations in multiple integrals
  • Explore polar coordinate transformations and their applications in integration
  • Investigate the properties of ellipses and their transformations to circles
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Students and educators in calculus, particularly those tackling double integrals and coordinate transformations, as well as mathematicians interested in advanced integration techniques.

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Homework Statement



\int\int x^2 dA where the area D is boundd by the ellipse 5x^2 + 4xy + y^2 = 1.

Homework Equations





The Attempt at a Solution



I'm not sure where to start this question. A few ideas I'm exploring are: 1. rewrite in polar co-ordinates (not sure how to write an ellipse in this form!), or 2. do a transformation from this ellipse to a circle (not sure how to do this either).

I anyone can suggest which method is more correct and get me started with a general idea of how to approach the problem, i would greatly appreciate it!

Thank you.
 
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I would probably try to tackle it by changing variables to get it into a circle. I think I know how I would first try to do it, but I don't know if you'd know the method (and I don't remember if there's an easier, more straightforward way to see the transformation). Basically, I would write the left hand side of the equation for your ellipse as

\mathbf{r}^{\mathsf{T}}\mathsf{A}\mathbf{r} = 1

where \mathbf{r} is a column vector with entries x and y and \mathsf{A} is a 2 x 2 matrix. I would then find the eigenvalues of the matrix A and diagonalize it. Once diagonalized you might recall that you can write \mathsf{A} = \mathsf{P}^{-1}\mathsf{D}\mathsf{P}, where D is a diagonal matrix. Then define \mathbf{r}' = P\mathbf{r}. This defines news coordinates with the x' and y' axes along the major and minor axes of the ellipse. i.e., the equation for the ellipse in terms of x' and y' will be

\left(\frac{x'}{a}\right)^2 + \left(\frac{y'}{b}\right)^2 = 1,

where a and b are constants determined by your transformation. If you don't know the linear algebra to do all this, basically what you're trying to do is find a transformation

x' = Ax + By,
y' = Cx + Dy,

such that you get the above equation for the ellipse in terms of x' and y' (i.e., no xy, or x or y terms). Once you get to that point, you can define new variables u = (x'/a) and v = y'/b, which gives you the equation for a circle.

You then need to find the Jacobian to change variables in the integral to an integral over u and v.

Uh... was that helpful at all for you? Should I try to think of something simpler?
 
Yeah I definitely think that change of variables is reasonable, I just think there's any easier way to turn this into a circle than this matrix approach. Hmmm...
 

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