Diameter (original) (raw)

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Straight line segment that passes through the centre of a circle

Circle with

diameter D

radius R

centre or origin O

In geometry, a diameter of a circle is any straight line segment that passes through the centre of the circle and whose endpoints lie on the circle. It can also be defined as the longest chord of the circle. Both definitions are also valid for the diameter of a sphere.

In more modern usage, the length d {\displaystyle d} {\displaystyle d} of a diameter is also called the diameter. In this sense one speaks of the diameter rather than a diameter (which refers to the line segment itself), because all diameters of a circle or sphere have the same length, this being twice the radius r . {\displaystyle r.} {\displaystyle r.}

d = 2 r or equivalently r = d 2 . {\displaystyle d=2r\qquad {\text{or equivalently}}\qquad r={\frac {d}{2}}.} {\displaystyle d=2r\qquad {\text{or equivalently}}\qquad r={\frac {d}{2}}.}

For a convex shape in the plane, the diameter is defined to be the largest distance that can be formed between two opposite parallel lines tangent to its boundary, and the width is often defined to be the smallest such distance. Both quantities can be calculated efficiently using rotating calipers.[1] For a curve of constant width such as the Reuleaux triangle, the width and diameter are the same because all such pairs of parallel tangent lines have the same distance.

For an ellipse, the standard terminology is different. A diameter of an ellipse is any chord passing through the centre of the ellipse.[2] For example, conjugate diameters have the property that a tangent line to the ellipse at the endpoint of one diameter is parallel to the conjugate diameter. The longest diameter is called the major axis.

The word "diameter" is derived from Ancient Greek: διάμετρος (diametros), "diameter of a circle", from διά (dia), "across, through" and μέτρον (metron), "measure".[3] It is often abbreviated DIA , dia , d , {\displaystyle {\text{DIA}},{\text{dia}},d,} {\displaystyle {\text{DIA}},{\text{dia}},d,} or ∅ . {\displaystyle \varnothing .} {\displaystyle \varnothing .}

The definitions given above are only valid for circles, spheres and convex shapes. However, they are special cases of a more general definition that is valid for any kind of n {\displaystyle n} {\displaystyle n}-dimensional (convex or non-convex) object, such as a hypercube or a set of scattered points. The diameter or metric diameter of a subset of a metric space is the least upper bound of the set of all distances between pairs of points in the subset. Explicitly, if S {\displaystyle S} {\displaystyle S} is the subset and if ρ {\displaystyle \rho } {\displaystyle \rho } is the metric, the diameter is diam ⁡ ( S ) = sup x , y ∈ S ρ ( x , y ) . {\displaystyle \operatorname {diam} (S)=\sup _{x,y\in S}\rho (x,y).} {\displaystyle \operatorname {diam} (S)=\sup _{x,y\in S}\rho (x,y).}

If the metric ρ {\displaystyle \rho } {\displaystyle \rho } is viewed here as having codomain R {\displaystyle \mathbb {R} } {\displaystyle \mathbb {R} } (the set of all real numbers), this implies that the diameter of the empty set (the case S = ∅ {\displaystyle S=\varnothing } {\displaystyle S=\varnothing }) equals − ∞ {\displaystyle -\infty } {\displaystyle -\infty } (negative infinity). Some authors prefer to treat the empty set as a special case, assigning it a diameter of 0 , {\displaystyle 0,} {\displaystyle 0,}[4] which corresponds to taking the codomain of ρ {\displaystyle \rho } {\displaystyle \rho } to be the set of nonnegative reals.

For any solid object or set of scattered points in n {\displaystyle n} {\displaystyle n}-dimensional Euclidean space, the diameter of the object or set is the same as the diameter of its convex hull. In medical terminology concerning a lesion or in geology concerning a rock, the diameter of an object is the least upper bound of the set of all distances between pairs of points in the object.

In differential geometry, the diameter is an important global Riemannian invariant.

In planar geometry, a diameter of a conic section is typically defined as any chord which passes through the conic's centre; such diameters are not necessarily of uniform length, except in the case of the circle, which has eccentricity e = 0. {\displaystyle e=0.} {\displaystyle e=0.}

Sign ⌀ in a technical drawing

A photographic filter marked as having a 58mm thread diameter

The symbol or variable for diameter, ⌀, is sometimes used in technical drawings or specifications as a prefix or suffix for a number (e.g. "⌀ 55 mm"), indicating that it represents diameter.[5] Photographic filter thread sizes are often denoted in this way.[6]

The symbol has a code point in Unicode at U+2300 ⌀ DIAMETER SIGN, in the Miscellaneous Technical set. It should not be confused with several other characters (such as U+00D8 Ø LATIN CAPITAL LETTER O WITH STROKE or U+2205 ∅ EMPTY SET) that resemble it but have unrelated meanings.[7] It has the compose sequence Composedi.[8]

Diameter vs. radius

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The diameter of a circle is exactly twice its radius. However, this is true only for a circle, and only in the Euclidean metric. Jung's theorem provides more general inequalities relating the diameter to the radius.

  1. ^ Toussaint, Godfried T. (1983). "Solving geometric problems with the rotating calipers" (PDF). Proc. MELECON '83. Mediterranean Electrotechnical Conference, 24–26 May 1983, Athens. IEEE. CiteSeerX 10.1.1.155.5671. (pdf pages in reversed order)
  2. ^ Bogomolny, Alexander. "Conjugate Diameters in Ellipse". www.cut-the-knot.org.
  3. ^ "Diameter—Origin and meaning of diameter by Online Etymology Dictionary". www.etymonline.com.
  4. ^ "Re: diameter of an empty set". at.yorku.ca.
  5. ^ Puncochar, Daniel E. (1997). Interpretation of Geometric Dimensioning and Tolerancing. Industrial Press Inc. p. 5. ISBN 9780831130725.
  6. ^ Ciaglia, Joseph (2002). Introduction to Digital Photography. Prentice Hall. p. 9. ISBN 9780130321367. The filter diameter (in mm) usually follows the symbol ⌀
  7. ^ Korpela, Jukka K. (2006). Unicode Explained. O'Reilly Media, Inc. p. 171. ISBN 9780596101213.
  8. ^ Monniaux, David. "UTF-8 (Unicode) compose sequence". Retrieved 2018-07-13.

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