Spherical cap

File:Spherical cap diagram.tiff

In geometry, a spherical cap or spherical dome is a portion of a sphere or of a ball cut off by a plane. It is also a spherical segment of one base, i.e., bounded by a single plane. If the plane passes through the center of the sphere (forming a great circle), so that the height of the cap is equal to the radius of the sphere, the spherical cap is called a hemisphere.

The volume of the spherical cap and the area of the curved surface may be calculated using combinations of

• The radius ${\displaystyle r}$ of the sphere
• The radius ${\displaystyle a}$ of the base of the cap
• The height ${\displaystyle h}$ of the cap
• The polar angle ${\displaystyle \theta }$ between the rays from the center of the sphere to the apex of the cap (the pole) and the edge of the disk forming the base of the cap.

These variables are inter-related through the formulas ${\displaystyle a=r\sin \theta }$, ${\displaystyle h=r(1-\cos \theta )}$, ${\displaystyle 2hr=a^2+h^2}$, and ${\displaystyle 2ha=(a^2+h^2)\sin \theta }$.

	Using ${\displaystyle r}$ and ${\displaystyle h}$	Using ${\displaystyle a}$ and ${\displaystyle h}$	Using ${\displaystyle r}$ and ${\displaystyle \theta }$
Volume	${\displaystyle V=\frac{\pi h^2}{3}(3r-h)}$ [1]	${\displaystyle V=\frac{1}{6}\pi h(3a^2+h^2)}$	${\displaystyle V=\frac{\pi }{3}{r}^3(2+\cos \theta )(1-\cos \theta {)}^2}$
Area	${\displaystyle A=2\pi rh}$[1]	${\displaystyle A=\pi (a^2+h^2)}$	${\displaystyle A=2\pi r^2(1-\cos \theta )}$
Constraints	${\displaystyle 0\le h\le 2r}$	${\displaystyle 0\le a,0\le h}$	${\displaystyle 0\le \theta \le \pi ,0\le r}$

If ${\displaystyle \varphi }$ denotes the latitude in geographic coordinates, then ${\displaystyle \theta +\varphi =\pi /2=90^{\circ }}$, and ${\displaystyle \cos \theta =\sin \varphi }$.

Note that aside from the calculus based argument below, the area of the spherical cap may be derived from the volume ${\displaystyle V_{sec}}$ of the spherical sector, by an intuitive argument,^[2] as

${\displaystyle A=\frac{3}{r}{V}_{sec}=\frac{3}{r}\frac{2\pi r^{2}h}{3}=2\pi rh.}$

The intuitive argument is based upon summing the total sector volume from that of infinitesimal triangular pyramids. Utilizing the pyramid (or cone) volume formula of ${\displaystyle V=\frac{1}{3}b{h}^{\prime }}$, where ${\displaystyle b}$ is the infinitesimal area of each pyramidal base (located on the surface of the sphere) and ${\displaystyle h^{\prime }}$ is the height of each pyramid from its base to its apex (at the center of the sphere). Since each ${\displaystyle h^{\prime }}$, in the limit, is constant and equivalent to the radius ${\displaystyle r}$ of the sphere, the sum of the infinitesimal pyramidal bases would equal the area of the spherical sector, and:

${\displaystyle V_{sec}=\sum V=\sum \frac{1}{3}b{h}^{\prime }=\sum \frac{1}{3}br=\frac{r}{3}\sum b=\frac{r}{3}A}$

File:Spherical cap from rotation.svg

The volume and area formulas may be derived by examining the rotation of the function

${\displaystyle f(x)=\sqrt{r^2-(x-r{)}^2}=\sqrt{2rx-x^2}}$

for ${\displaystyle x\in [0,h]}$, using the formulas the surface of the rotation for the area and the solid of the revolution for the volume. The area is

${\displaystyle A=2\pi {\displaystyle \underset{0}{\overset{h}{\int }}}f(x)\sqrt{1+f^{\prime }(x{)}^2}dx}$

The derivative of ${\displaystyle f}$ is

${\displaystyle f^{\prime }(x)=\frac{r-x}{\sqrt{2rx-x^2}}}$

and hence

${\displaystyle 1+f^{\prime }(x{)}^2=\frac{r^2}{2rx-x^2}}$

The formula for the area is therefore

${\displaystyle A=2\pi {\displaystyle \underset{0}{\overset{h}{\int }}}\sqrt{2rx-x^2}\sqrt{\frac{r^2}{2rx-x^2}}dx=2\pi {\displaystyle \underset{0}{\overset{h}{\int }}}rdx=2\pi r{\left[x\right]}_0^h=2\pi rh}$

The volume is

${\displaystyle V=\pi {\displaystyle \underset{0}{\overset{h}{\int }}}f(x{)}^{2}dx=\pi {\displaystyle \underset{0}{\overset{h}{\int }}}(2rx-x^2)dx=\pi {[r{x}^2-\frac{1}{3}{x}^3]}_0^h=\frac{\pi h^2}{3}(3r-h)}$

The moments of inertia of a spherical cap (where the z-axis is the symmetrical axis) about the principal axes (center) of the sphere are:

${\displaystyle J_{zz,\text{cap}}=\frac{mh(3h^2-15hR+20R^2)}{10(3R-h)}}$

${\displaystyle J_{xx,\text{cap}}=J_{yy,\text{cap}}=\frac{m(-9h^3+45h^{2}R-80h{R}^2+60R^3)}{20(3R-h)}}$

where m and h are, respectively, the mass and height of the spherical cap and R is the radius of the entire sphere.

The volume of the union of two intersecting spheres of radii ${\displaystyle r_1}$ and ${\displaystyle r_2}$ is ^[3]

${\displaystyle V=V^{(1)}-V^{(2)},}$

where

${\displaystyle V^{(1)}=\frac{4\pi }{3}{r}_1^3+\frac{4\pi }{3}{r}_2^3}$

is the sum of the volumes of the two isolated spheres, and

${\displaystyle V^{(2)}=\frac{\pi h_1^2}{3}(3r_1-h_1)+\frac{\pi h_2^2}{3}(3r_2-h_2)}$

the sum of the volumes of the two spherical caps forming their intersection. If ${\displaystyle d\le r_1+r_2}$ is the distance between the two sphere centers, elimination of the variables ${\displaystyle h_1}$ and ${\displaystyle h_2}$ leads to^[4][5]

${\displaystyle V^{(2)}=\frac{\pi }{12d}(r_1+r_2-d{)}^2(d^2+2d(r_1+r_2)-3(r_1-r_2{)}^2).}$

The volume of a spherical cap with a curved base can be calculated by considering two spheres with radii ${\displaystyle r_1}$ and ${\displaystyle r_2}$, separated by some distance ${\displaystyle d}$, and for which their surfaces intersect at ${\displaystyle x=h}$. That is, the curvature of the base comes from sphere 2. The volume is thus the difference between sphere 2's cap (with height ${\displaystyle (r_2-r_1)-(d-h)}$) and sphere 1's cap (with height ${\displaystyle h}$),

${\displaystyle \begin{array}{cc}V& =\frac{\pi h^2}{3}(3r_1-h)-\frac{\pi [(r_2-r_1)-(d-h){]}^2}{3}[3r_2-((r_2-r_1)-(d-h))],\\ V& =\frac{\pi h^2}{3}(3r_1-h)-\frac{\pi }{3}(d-h{)}^3{(\frac{r_2-r_1}{d-h}-1)}^2[\frac{2r_2+r_1}{d-h}+1].\end{array}}$

This formula is valid only for configurations that satisfy ${\displaystyle 0<d<r_2}$ and ${\displaystyle d-(r_2-r_1)<h\le r_1}$. If sphere 2 is very large such that ${\displaystyle r_2\gg r_1}$, hence ${\displaystyle d\gg h}$ and ${\displaystyle r_2\approx d}$, which is the case for a spherical cap with a base that has a negligible curvature, the above equation is equal to the volume of a spherical cap with a flat base, as expected.

Consider two intersecting spheres of radii ${\displaystyle r_1}$ and ${\displaystyle r_2}$, with their centers separated by distance ${\displaystyle d}$. They intersect if

${\displaystyle |r_1-r_2|\le d\le r_1+r_2}$

From the law of cosines, the polar angle of the spherical cap on the sphere of radius ${\displaystyle r_1}$ is

${\displaystyle \cos \theta =\frac{r_1^2-r_2^2+d^2}{2r_{1}d}}$

Using this, the surface area of the spherical cap on the sphere of radius ${\displaystyle r_1}$ is

${\displaystyle A_1=2\pi r_1^2(1+\frac{r_2^2-r_1^2-d^2}{2r_{1}d})}$

The curved surface area of the spherical segment bounded by two parallel disks is the difference of surface areas of their respective spherical caps. For a sphere of radius ${\displaystyle r}$, and caps with heights ${\displaystyle h_1}$ and ${\displaystyle h_2}$, the area is

${\displaystyle A=2\pi r|h_1-h_2|,}$

or, using geographic coordinates with latitudes ${\displaystyle {\varphi }_1}$ and ${\displaystyle {\varphi }_2}$,^[6]

${\displaystyle A=2\pi r^2|\sin {\varphi }_1-\sin {\varphi }_2|,}$

For example, assuming the Earth is a sphere of radius 6371 km, the surface area of the arctic (north of the Arctic Circle, at latitude 66.56° as of August 2016^[7]) is 2π ⋅ 6371² |sin 90° − sin 66.56°| = 21.04 million km² (8.12 million mi²), or 0.5 ⋅ |sin 90° − sin 66.56°| = 4.125% of the total surface area of the Earth.

This formula can also be used to demonstrate that half the surface area of the Earth lies between latitudes 30° South and 30° North in a spherical zone which encompasses all of the tropics.

The spheroidal dome is obtained by sectioning off a portion of a spheroid so that the resulting dome is circularly symmetric (having an axis of rotation), and likewise the ellipsoidal dome is derived from the ellipsoid.

Generally, the ${\displaystyle n}$-dimensional volume of a hyperspherical cap of height ${\displaystyle h}$ and radius ${\displaystyle r}$ in ${\displaystyle n}$-dimensional Euclidean space is given by:^[8] $${\displaystyle V=\frac{{\pi }^{\frac{n-1}{2}}{r}^n}{\Gamma \left(\frac{n+1}{2}\right)}{\displaystyle \underset{0}{\overset{\arccos \left(\frac{r-h}{r}\right)}{\int }}}{\sin }^n(\theta )\mathrm{d}\theta }$$ where ${\displaystyle \Gamma }$ (the gamma function) is given by ${\displaystyle \Gamma (z)={\displaystyle \underset{0}{\overset{\mathrm{\infty }}{\int }}}{t}^{z-1}{\mathrm{e}}^{-t}\mathrm{d}t}$.

The formula for ${\displaystyle V}$ can be expressed in terms of the volume of the unit n-ball $C_n={\pi }^{n/2}/\Gamma [1+\frac{n}{2}]$ and the hypergeometric function ${\displaystyle {}_2{F}_1}$ or the regularized incomplete beta function ${\displaystyle I_x(a,b)}$ as $${\displaystyle V=C_n{r}^n(\frac{1}{2}-\frac{r-h}{r}\frac{\Gamma [1+\frac{n}{2}]}{\sqrt{\pi }\Gamma [\frac{n+1}{2}]}{}_2{F}_1(\frac{1}{2},\frac{1-n}{2};\frac{3}{2};{\left(\frac{r-h}{r}\right)}^2))=\frac{1}{2}{C}_n{r}^n{I}_{(2rh-h^2)/r^2}(\frac{n+1}{2},\frac{1}{2}),}$$

and the area formula ${\displaystyle A}$ can be expressed in terms of the area of the unit n-ball $A_n=2{\pi }^{n/2}/\Gamma [\frac{n}{2}]$ as $${\displaystyle A=\frac{1}{2}{A}_n{r}^{n-1}{I}_{(2rh-h^2)/r^2}(\frac{n-1}{2},\frac{1}{2}),}$$ where ${\displaystyle 0\le h\le r}$.

A. Chudnov^[9] derived the following formulas: $${\displaystyle A=A_n{r}^{n-1}{p}_{n-2}(q),V=C_n{r}^n{p}_n(q),}$$ where $${\displaystyle q=1-h/r(0\le q\le 1),p_n(q)=(1-G_n(q)/G_n(1))/2,}$$ $${\displaystyle G_n(q)={\displaystyle \underset{0}{\overset{q}{\int }}}(1-t^2{)}^{(n-1)/2}dt.}$$

For odd ${\displaystyle n=2k+1}$: $${\displaystyle G_n(q)={\displaystyle \sum _{i=0}^k}(-1{)}^i(\genfrac{}{}{0ex}{}{k}{i})\frac{q^{2i+1}}{2i+1}.}$$

If ${\displaystyle n\to \mathrm{\infty }}$ and ${\displaystyle q\sqrt{n}=\text{const.}}$, then ${\displaystyle p_n(q)\to 1-F(q\sqrt{n})}$ where ${\displaystyle F}$ is the integral of the standard normal distribution.^[10]

A more quantitative bound is ${\displaystyle A/(A_n{r}^{n-1})=n^{\Theta (1)}\cdot [(2-h/r)h/r{]}^{n/2}}$. For large caps (that is when ${\displaystyle (1-h/r{)}^4\cdot n=O(1)}$ as ${\displaystyle n\to \mathrm{\infty }}$), the bound simplifies to ${\displaystyle n^{\Theta (1)}\cdot e^{-(1-h/r{)}^{2}n/2}}$.^[11]

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• Circular segment — the analogous 2D object
• Solid angle — contains formula for n-sphere caps
• Spherical segment
• Spherical sector
• Spherical wedge

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• Lua error in Module:Citation/CS1/Configuration at line 2172: attempt to index field '?' (a nil value). Derivation and some additional formulas.
• Online calculator for spherical cap volume and area.
• Summary of spherical formulas.