Consider two points in the 2D Euclidean plane, the origin $0$ and $x$. One can define a co-ordinate system such that for any point $y$ in the plane, $y$ is parametrized by its distance from $0$, call it $r$, and its distance from $x$, call it $L$, and a binary choice, say $+$ or $-$. How does one transform this co-ordinate system with the Cartesian coordinate system, and what is the integrating factor (i.e. area element)?
Circle-Circle intersection coordinate system
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multivariable-calculus
analytic-geometry
coordinate-systems
vector-analysis
polar-coordinates
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1http://en.wikipedia.org/wiki/Two-center_bipolar_coordinates This is what you are looking for. – 2012-08-12
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0That's great, thanks! Is there anything like that for higher dimensions? (Again parametrized by the distance to two centers, with the other parameter being an element $\xi \in S^{d-2} $ ? – 2012-08-12
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0@Robert: why not? You've pretty much defined it yourself. – 2012-08-12
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0True, but I'd like to know if the volume element (a.k.a. integrating factor) is worked out anywhere of arbitrary dimensions. – 2012-08-12
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0I suppose you'd want $n$ distances from $n$ points in $\mathbb{R}^n$ to pin down location of a point to two possible points. – 2012-08-13
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0"That's great, thanks! Is there anything like that for higher dimensions?" - look up bispherical and toroidal coordinates. – 2012-08-13