MyOpenMath/Solutions/Toroid inductance

This is a good example of how a double integral can be used to find the volume of shapes with a high degree of symmetry. Let ${\displaystyle V}$  denote a volume and ${\displaystyle A}$  denote an area, with the understanding that ${\displaystyle dV}$  denote a volume and ${\displaystyle dA}$  are differentials that can be integrated as the limit of Reimmann sums. The figure to the right resembles that of a rectangular washer that had its top surface shaved down. The rectangular area shaded in yellow is an area differential:

${\displaystyle dA=h\,dr}$ 

where ${\displaystyle h=h(r)}$  is a function of ${\displaystyle r}$ . For example, the function might be ${\displaystyle h(r)=Cr^{-\alpha },}$  where ${\displaystyle C}$  and ${\displaystyle \alpha }$  are constants. This function is defined with a range defined by two other constants ${\displaystyle (r_{1},r_{2})}$ :

${\displaystyle r_{1}<r<r_{2}}$ 

The figure shows two identical cross-sectional areas that can be integrated as, ${\displaystyle \int _{r_{1}}^{r_{2}}Cr^{-\alpha }\,dr}$ , but this step would be premature. Instead we sweep the rectangle of differential (small) area ${\displaystyle h\,dr}$  around the circumference ${\displaystyle 2\pi }$  to obtain the differential volume:

${\displaystyle dV=2\pi r\,dA=2\pi r\,h(r)dr}$ 

${\displaystyle V=2\pi C\int _{r_{1}}^{r_{2}}r^{-\alpha +1}dr}$ 

Note how this technique offers a simple proof for the area of a circle, assuming that the circumference is known to be 2πr.

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