| steradian | |
| Standard: | SI |
| Quantity: | solid angle |
| Symbol: | sr |
| Units1: | SI base units |
| Inunits1: | 1 m2/m2 |
| Units2: | square degrees |
| Inunits2: | deg2 ≈ deg2 |
The steradian (symbol: sr) or square radian[1] [2] is the unit of solid angle in the International System of Units (SI). It is used in three dimensional geometry, and is analogous to the radian, which quantifies planar angles. A solid angle in the form of a right circular cone can be projected onto a sphere, defining a spherical cap where the cone intersects the sphere. The magnitude of the solid angle expressed in steradians is defined as the quotient of the surface area of the spherical cap and the square of the sphere's radius. This is analogous to the way a plane angle projected onto a circle defines a circular arc on the circumference, whose length is proportional to the angle. Steradians can be used to measure a solid angle of any shape. The solid angle subtended is the same as that of a cone with the same projected area.
In the SI, solid angle is considered to be a dimensionless quantity, the ratio of the area projected onto a surrounding sphere and the square of the sphere's radius. This is the number of square radians in the solid angle. This means that the SI steradian is the number of square radians in a solid angle equal to one square radian, which of course is the number one. It is useful to distinguish between dimensionless quantities of a different kind, such as the radian (in the SI, a ratio of quantities of dimension length), so the symbol sr is used. For example, radiant intensity can be measured in watts per steradian (W⋅sr−1). The steradian was formerly an SI supplementary unit, but this category was abolished in 1995 and the steradian is now considered an SI derived unit.
The name steradian is derived from the Greek Greek, Ancient (to 1453);: στερεός 'solid' + radian.
A steradian can be defined as the solid angle subtended at the centre of a unit sphere by a unit area (of any shape) on its surface. For a general sphere of radius, any portion of its surface with area subtends one steradian at its centre.[3]
A solid angle in the form of a circular cone is related to the area it cuts out of a sphere:
\Omega=
| A | |
| r2 |
sr=
| 2\pih | |
| r |
sr,
2\pirh
Because the surface area of a sphere is, the definition implies that a sphere subtends steradians (≈ 12.56637 sr) at its centre, or that a steradian subtends of a sphere. By the same argument, the maximum solid angle that can be subtended at any point is .
The area of a spherical cap is, where is the "height" of the cap. If, then
\tfrac{h}{r}=\tfrac{1}{2\pi}
\theta=\arccos\left(
| r-h | |
| r |
\right)=\arccos\left(1-
| h | |
| r |
\right)=\arccos\left(1-
| 1 | |
| 2\pi |
\right),
giving 0.572 rad or 32.77° and 1.144 rad or 65.54°.
The solid angle of a simple cone whose cross-section subtends the angle is:
\Omega=2\pi(1-\cos\theta)sr=
| ||||
| 4\pi\sin |
\right)sr.
A steradian is also equal to
\tfrac{1}{4\pi}
\left(\tfrac{360\circ}{2\pi}\right)2
Millisteradians (msr) and microsteradians (μsr) are occasionally used to describe light and particle beams.[4] [5] Other multiples are rarely used.