Radius

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Short description: Segment in a circle or sphere from its center to its perimeter or surface and its length
Circle with:
  circumference C
  diameter D
  radius R
  center or origin O

In classical geometry, a radius (pl.: radii or radiuses)[lower-alpha 1] of a circle or sphere is any of the line segments from its center to its perimeter, and in more modern usage, it is also their length. The name comes from the Latin radius, meaning ray but also the spoke of a chariot wheel.[2] The typical abbreviation and mathematical variable name for radius is R or r. By extension, the diameter D is defined as twice the radius:[3]

[math]\displaystyle{ d \doteq 2r \quad \Rightarrow \quad r = \frac d 2. }[/math]

If an object does not have a center, the term may refer to its circumradius, the radius of its circumscribed circle or circumscribed sphere. In either case, the radius may be more than half the diameter, which is usually defined as the maximum distance between any two points of the figure. The inradius of a geometric figure is usually the radius of the largest circle or sphere contained in it. The inner radius of a ring, tube or other hollow object is the radius of its cavity.

For regular polygons, the radius is the same as its circumradius.[4] The inradius of a regular polygon is also called apothem. In graph theory, the radius of a graph is the minimum over all vertices u of the maximum distance from u to any other vertex of the graph.[5]

The radius of the circle with perimeter (circumference) C is

[math]\displaystyle{ r = \frac C {2\pi} }[/math]

Formula

For many geometric figures, the radius has a well-defined relationship with other measures of the figure.

Circles

The radius of a circle with area A is

[math]\displaystyle{ r = \sqrt{\frac{A}{\pi}}. }[/math]

The radius of the circle that passes through the three non-collinear points P1, P2, and P3 is given by

[math]\displaystyle{ r=\frac{|\vec{OP_1}-\vec{OP_3}|}{2\sin\theta}, }[/math]

where θ is the angle P1P2P3. This formula uses the law of sines. If the three points are given by their coordinates (x1,y1), (x2,y2), and (x3,y3), the radius can be expressed as

[math]\displaystyle{ r = \frac {\sqrt{\bigl((x_2 - x_1)^2 + (y_2 - y_1)^2\bigr) \bigl((x_2 - x_3)^2 + (y_2 - y_3)^2\bigr) \bigl((x_3 - x_1)^2 + (y_3 - y_1)^2 \bigr)} }{ 2\bigl| x_1 y_2 + x_2 y_3 + x_3 y_1 - x_1 y_3 - x_2 y_1 - x_3 y_2\bigr| }. }[/math]

Regular polygons

n Rn
3 0.577350...
4 0.707106...
5 0.850650...
6 1.0
7 1.152382...
8 1.306562...
9 1.461902...
10 1.618033...
A square, for example (n=4)

The radius r of a regular polygon with n sides of length s is given by r = Rn s, where [math]\displaystyle{ R_n = 1\left/\left(2 \sin \frac\pi n \right)\right. . }[/math] Values of Rn for small values of n are given in the table. If s = 1 then these values are also the radii of the corresponding regular polygons.


Hypercubes

The radius of a d-dimensional hypercube with side s is

[math]\displaystyle{ r = \frac{s}{2}\sqrt{d}. }[/math]

Use in coordinate systems

Polar coordinates

The polar coordinate system is a two-dimensional coordinate system in which each point on a plane is determined by a distance from a fixed point and an angle from a fixed direction.

The fixed point (analogous to the origin of a Cartesian system) is called the pole, and the ray from the pole in the fixed direction is the polar axis. The distance from the pole is called the radial coordinate or radius, and the angle is the angular coordinate, polar angle, or azimuth.[6]

Cylindrical coordinates

In the cylindrical coordinate system, there is a chosen reference axis and a chosen reference plane perpendicular to that axis. The origin of the system is the point where all three coordinates can be given as zero. This is the intersection between the reference plane and the axis.

The axis is variously called the cylindrical or longitudinal axis, to differentiate it from the polar axis, which is the ray that lies in the reference plane, starting at the origin and pointing in the reference direction.

The distance from the axis may be called the radial distance or radius, while the angular coordinate is sometimes referred to as the angular position or as the azimuth. The radius and the azimuth are together called the polar coordinates, as they correspond to a two-dimensional polar coordinate system in the plane through the point, parallel to the reference plane. The third coordinate may be called the height or altitude (if the reference plane is considered horizontal), longitudinal position,[7] or axial position.[8]

Spherical coordinates

In a spherical coordinate system, the radius describes the distance of a point from a fixed origin. Its position if further defined by the polar angle measured between the radial direction and a fixed zenith direction, and the azimuth angle, the angle between the orthogonal projection of the radial direction on a reference plane that passes through the origin and is orthogonal to the zenith, and a fixed reference direction in that plane.

See also


Notes

  1. The plural of radius can be either radii (from the Latin plural) or the conventional English plural radiuses.[1]

References

  1. "Radius - Definition and More from the Free Merriam-Webster Dictionary". Merriam-webster.com. http://www.merriam-webster.com/dictionary/radius. 
  2. Definition of Radius at dictionary.reference.com. Accessed on 2009-08-08.
  3. Definition of radius at mathwords.com. Accessed on 2009-08-08.
  4. Barnett Rich, Christopher Thomas (2008), Schaum's Outline of Geometry, 4th edition, 326 pages. McGraw-Hill Professional. ISBN 0-07-154412-7, ISBN 978-0-07-154412-2. Online version accessed on 2009-08-08.
  5. Jonathan L. Gross, Jay Yellen (2006), Graph theory and its applications. 2nd edition, 779 pages; CRC Press. ISBN 1-58488-505-X, 9781584885054. Online version accessed on 2009-08-08.
  6. Brown, Richard G. (1997). Andrew M. Gleason. ed. Advanced Mathematics: Precalculus with Discrete Mathematics and Data Analysis. Evanston, Illinois: McDougal Littell. ISBN 0-395-77114-5. https://archive.org/details/advancedmathemat00rich_0. 
  7. Krafft, C.; Volokitin, A. S. (1 January 2002). "Resonant electron beam interaction with several lower hybrid waves". Physics of Plasmas 9 (6): 2786–2797. doi:10.1063/1.1465420. ISSN 1089-7674. Bibcode2002PhPl....9.2786K. http://pop.aip.org/resource/1/phpaen/v9/i6/p2786_s1?isAuthorized=no. Retrieved 9 February 2013. "...in cylindrical coordinates (r,θ,z) ... and Z=vbzt is the longitudinal position...". 
  8. Groisman, Alexander; Steinberg, Victor (1997-02-24). "Solitary Vortex Pairs in Viscoelastic Couette Flow". Physical Review Letters (American Physical Society (APS)) 78 (8): 1460–1463. doi:10.1103/physrevlett.78.1460. ISSN 0031-9007. Bibcode1997PhRvL..78.1460G.  "[...]where r, θ, and z are cylindrical coordinates [...] as a function of axial position[...]"