All regular
simple polygons (a simple polygon is one that does not intersect itself anywhere) are convex. Those having the same number of sides are also
similar. An
n-sided convex regular polygon is denoted by its
Schläfli symbol \{n\}. For n, we have two
degenerate cases: ;
Monogon {1}; point: Degenerate in
ordinary space. (Most authorities do not regard the monogon as a true polygon, partly because of this, and also because the formulae below do not work, and its structure is not that of any
abstract polygon.) ;
Digon {2}; line segment: Degenerate in
ordinary space. (Some authorities do not regard the digon as a true polygon because of this.) In certain contexts all the polygons considered will be regular. In such circumstances it is customary to drop the prefix regular. For instance, all the faces of
uniform polyhedra must be regular and the faces will be described simply as triangle, square, pentagon, etc. chord formula, the area bounded by the
circumcircle and
incircle of every unit convex regular polygon is /4
Angles For a regular convex
n-gon, each
interior angle has a measure of: : \frac{(n - 2)180}{n} degrees; : \frac{(n - 2)\pi}{n} radians; or : \frac{(n - 2)}{2n}=\frac{1}{2}-\frac{1}{n} full
turns, and each
exterior angle (i.e.,
supplementary to the interior angle) has a measure of \tfrac{360}{n} degrees, with the sum of the exterior angles equal to 360 degrees or 2π radians or one full turn. As
n approaches infinity, the internal angle approaches 180 degrees. For a regular polygon with 10,000 sides (a
myriagon) the internal angle is 179.964°. As the number of sides increases, the internal angle can come very close to 180°, and the shape of the polygon approaches that of a circle. However the polygon can never become a circle. The value of the internal angle can never become exactly equal to 180°, as the circumference would effectively become a straight line (see
apeirogon). For this reason, a circle is not a polygon with an infinite number of sides.
Diagonals For n>2, the number of
diagonals is \tfrac{1}{2}n(n - 3); i.e., 0, 2, 5, 9, ..., for a triangle, square, pentagon, hexagon, ... . The diagonals divide the polygon into 1, 4, 11, 24, ... pieces. For a regular
n-gon inscribed in a circle of radius 1, the product of the distances from a given vertex to all other vertices (including adjacent vertices and vertices connected by a diagonal) equals
n.
Points in the plane For a regular simple -gon with
circumradius and distances from an arbitrary point in the plane to the vertices, we have :\frac{1}{n}\sum_{i=1}^n d_i^4 + 3R^4 = \biggl(\frac{1}{n}\sum_{i=1}^n d_i^2 + R^2\biggr)^2. For higher powers of distances d_i from an arbitrary point in the plane to the vertices of a regular -gon, if :S^{(2m)}_{n}=\frac 1n\sum_{i=1}^n d_i^{2m}, then :S^{(2m)}_{n} = \left(S^{(2)}_{n}\right)^m + \sum_{k=1}^{\left\lfloor m/2\right\rfloor}\binom{m}{2k}\binom{2k}{k}R^{2k}\left(S^{(2)}_{n} - R^2\right)^k\left(S^{(2)}_{n}\right)^{m-2k}, and : S^{(2m)}_{n} = \left(S^{(2)}_{n}\right)^m + \sum_{k=1}^{\left\lfloor m/2\right\rfloor}\frac{1}{2^k}\binom{m}{2k}\binom{2k}{k} \left(S^{(4)}_{n} -\left(S^{(2)}_{n}\right)^2\right)^k\left(S^{(2)}_{n}\right)^{m-2k}, where is a positive integer less than . If is the distance from an arbitrary point in the plane to the centroid of a regular -gon with circumradius , then (the apothem being the distance from the center to any side). This is a generalization of
Viviani's theorem for the
n = 3 case.
Circumradius (
n = 5) with
side s,
circumradius R and
apothem a The
circumradius R from the center of a regular polygon to one of the vertices is related to the side length
s or to the
apothem a by :R = \frac{s}{2 \sin\left(\frac{\pi}{n}\right)} = \frac{a}{\cos\left(\frac{\pi}{n} \right)} \quad_,\quad a = \frac{s}{2 \tan\left(\frac{\pi}{n}\right)} For
constructible polygons,
algebraic expressions for these relationships exist . The sum of the perpendiculars from a regular
n-gon's vertices to any line tangent to the circumcircle equals
n times the circumradius. In particular, this is true for any regular polygon with an even number of sides, in which case the parallelograms are all rhombi. Regular polygons with 4m+2 sides can be dissected in a way with (2m+1)-fold radial symmetry. The list gives the number of solutions for smaller polygons.
Area The area
A of a convex regular
n-sided polygon having
side s,
circumradius R,
apothem a, and
perimeter p is given by \begin{align} A &= \tfrac{1}{2}nsa \\ &= \tfrac{1}{2}pa \\ &= \tfrac{1}{4}ns^2\cot\left(\tfrac{\pi}{n}\right) \\ &= na^2\tan\left(\tfrac{\pi}{n}\right) \\ &= \tfrac{1}{2}nR^2\sin\left(\tfrac{2\pi}{n}\right) \end{align} For regular polygons with side
s = 1, circumradius
R = 1, or apothem
a = 1, this produces the following table: (
Since \cot x \rightarrow 1/x as x \rightarrow 0, the area when s = 1 tends to n^2/4\pi as n grows large.) to
sixty sides. The size increases without bound as the number of sides approaches infinity. Of all
n-gons with a given perimeter, the one with the largest area is regular. == Constructible polygon==