Circumference
Template:Short description Template:For
In geometry, the circumference (Template:Etymology) is the perimeter of a circle or ellipse. The circumference is the arc length of the circle, as if it were opened up and straightened out to a line segment.<ref>Template:Citation</ref> More generally, the perimeter is the curve length around any closed figure. Circumference may also refer to the circle itself, that is, the locus corresponding to the edge of a disk. The Template:Em is the circumference, or length, of any one of its great circles.
CircleEdit
Template:Redirect The circumference of a circle is the distance around it, but if, as in many elementary treatments, distance is defined in terms of straight lines, this cannot be used as a definition. Under these circumstances, the circumference of a circle may be defined as the limit of the perimeters of inscribed regular polygons as the number of sides increases without bound.<ref>Template:Citation</ref> The term circumference is used when measuring physical objects, as well as when considering abstract geometric forms.
Relationship with Template:PiEdit
The circumference of a circle is related to one of the most important mathematical constants. This constant, pi, is represented by the Greek letter <math>\pi.</math> Its first few decimal digits are 3.141592653589793...<ref>Template:Cite OEIS</ref> Pi is defined as the ratio of a circle's circumference <math>C</math> to its diameter <math>d:</math><ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> <math display="block">\pi = \frac{C}{d}.</math>
Or, equivalently, as the ratio of the circumference to twice the radius. The above formula can be rearranged to solve for the circumference: <math display=block>{C} = \pi \cdot{d} = 2\pi \cdot{r}.\!</math>
The ratio of the circle's circumference to its radius is equivalent to <math>2\pi</math>.Template:Efn This is also the number of radians in one turn. The use of the mathematical constant Template:Pi is ubiquitous in mathematics, engineering, and science.
In Measurement of a Circle written circa 250 BCE, Archimedes showed that this ratio (written as <math>C/d,</math> since he did not use the name Template:Pi) was greater than 3Template:Sfrac but less than 3Template:Sfrac by calculating the perimeters of an inscribed and a circumscribed regular polygon of 96 sides.<ref>Template:Citation</ref> This method for approximating Template:Pi was used for centuries, obtaining more accuracy by using polygons of larger and larger number of sides. The last such calculation was performed in 1630 by Christoph Grienberger who used polygons with 1040 sides.
EllipseEdit
{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}} Some authors use circumference to denote the perimeter of an ellipse. There is no general formula for the circumference of an ellipse in terms of the semi-major and semi-minor axes of the ellipse that uses only elementary functions. However, there are approximate formulas in terms of these parameters. One such approximation, due to Euler (1773), for the canonical ellipse, <math display=block>\frac{x^2}{a^2} + \frac{y^2}{b^2} = 1,</math> is <math display=block>C_{\rm{ellipse}} \sim \pi \sqrt{2\left(a^2 + b^2\right)}.</math> Some lower and upper bounds on the circumference of the canonical ellipse with <math>a\geq b</math> are:<ref>Template:Cite journal</ref> <math display=block>2\pi b \leq C \leq 2\pi a,</math> <math display=block>\pi (a+b) \leq C \leq 4(a+b),</math> <math display=block>4\sqrt{a^2+b^2} \leq C \leq \pi \sqrt{2\left(a^2+b^2\right)}.</math>
Here the upper bound <math>2\pi a</math> is the circumference of a circumscribed concentric circle passing through the endpoints of the ellipse's major axis, and the lower bound <math>4\sqrt{a^2+b^2}</math> is the perimeter of an inscribed rhombus with vertices at the endpoints of the major and minor axes.
The circumference of an ellipse can be expressed exactly in terms of the complete elliptic integral of the second kind.<ref>Template:Citation</ref> More precisely, <math display=block>C_{\rm{ellipse}} = 4a \int_0^{\pi/2} \sqrt{1 - e^2 \sin^2\theta}\ d\theta,</math> where <math>a</math> is the length of the semi-major axis and <math>e</math> is the eccentricity <math>\sqrt{1 - b^2/a^2}.</math>
See alsoEdit
- Template:Annotated link
- Template:Annotated link
- Template:Annotated link
- Template:Annotated link
- Template:Annotated link