Area of Surface of Revolution/Parametric Form
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Theorem
Let $\SS$ be a surface of revolution such that:
- $\SS$ is embedded in a Cartesian $3$-space
- the axis of revolution of $\SS$ is aligned with the $x$-axis
- the curve $\CC$ being rotated to generate $\SS$ is the plane curve described by the parametric equations:
| \(\ds \quad \ \ \) | \(\ds x\) | \(=\) | \(\ds \map x t\) | |||||||||||
| \(\ds y\) | \(=\) | \(\ds \map y t\) |
- where $t$ is in the closed interval $\closedint a b$.
Then the area of $\SS$ is given by:
- $\ds \map \AA \SS = 2 \pi \int_a^b y \sqrt {\paren {\dfrac {\d x} {\d t} }^2 + \paren {\dfrac {\d y} {\d t} }^2} \rd t$
Proof
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Sources
- 2014: Christopher Clapham and James Nicholson: The Concise Oxford Dictionary of Mathematics (5th ed.) ... (previous) ... (next): area of a surface of revolution
- 2021: Richard Earl and James Nicholson: The Concise Oxford Dictionary of Mathematics (6th ed.) ... (previous) ... (next): area of a surface of revolution