Regular polygon explained

Regular polygon
Label1:Edges and vertices
Data1:

n

Label2:Schläfli symbol
Data2:

\{n\}

Label3:Coxeter–Dynkin diagram
Label4:Symmetry group
Data4:Dn, order 2n
Label5:Dual polygon
Data5:Self-dual
Label6:Area
(with side length

s

)
Data6:

A=\tfrac{1}{4}ns2\cot\left(

\pi
n

\right)

Label7:Internal angle
Data7:

(n-2) x

{\pi
}
Label8:Internal angle sum
Data8:

\left(n-2\right) x {\pi}

Label9:Inscribed circle diameter
Data9:

dIC=s\cot\left(

\pi
n

\right)

Label10:Circumscribed circle diameter
Data10:

dOC=s\csc\left(

\pi
n

\right)

Label11:Properties
Data11:Convex, cyclic, equilateral, isogonal, isotoxal

In Euclidean geometry, a regular polygon is a polygon that is direct equiangular (all angles are equal in measure) and equilateral (all sides have the same length). Regular polygons may be either convex, star or skew. In the limit, a sequence of regular polygons with an increasing number of sides approximates a circle, if the perimeter or area is fixed, or a regular apeirogon (effectively a straight line), if the edge length is fixed.

General properties

These properties apply to all regular polygons, whether convex or star.

A regular n-sided polygon has rotational symmetry of order n.

All vertices of a regular polygon lie on a common circle (the circumscribed circle); i.e., they are concyclic points. That is, a regular polygon is a cyclic polygon.

Together with the property of equal-length sides, this implies that every regular polygon also has an inscribed circle or incircle that is tangent to every side at the midpoint. Thus a regular polygon is a tangential polygon.

A regular n-sided polygon can be constructed with compass and straightedge if and only if the odd prime factors of n are distinct Fermat primes. See constructible polygon.

A regular n-sided polygon can be constructed with origami if and only if

n=2a3bp1pr

for some

r\inN

, where each distinct

pi

is a Pierpont prime.[1]

Symmetry

The symmetry group of an n-sided regular polygon is dihedral group Dn (of order 2n): D2, D3, D4, ... It consists of the rotations in Cn, together with reflection symmetry in n axes that pass through the center. If n is even then half of these axes pass through two opposite vertices, and the other half through the midpoint of opposite sides. If n is odd then all axes pass through a vertex and the midpoint of the opposite side.

Regular convex polygons

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 . For n < 3, we have two degenerate cases:

Monogon : 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 ; a "double 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.

    Angles

    For a regular convex n-gon, each interior angle has a measure of:

    180(n-2)
    n
    degrees;
    (n-2)\pi
    n
    radians; or
    (n-2)
    2n
    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 unit-radius circle, 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 n-gon with circumradius R and distances di from an arbitrary point in the plane to the vertices, we have[2]

    1
    n
    n
    \sum
    i=1
    4
    d
    i

    +3R4=l(

    1
    n
    n
    \sum
    i=1
    2
    d
    i

    +R2r)2.

    For higher powers of distances

    di

    from an arbitrary point in the plane to the vertices of a regular

    n

    -gon, if
    (2m)
    S=
    n
    1n\sum
    i=1

    n

    2m
    d
    i
    ,

    then[3]

    (2m)
    S
    n

    =

    (2)
    \left(S
    n

    \right)m+

    \left\lfloorm/2\right\rfloor
    \sum
    k=1

    \binom{m}{2k}\binom{2k}{k}R2k

    (2)
    \left(S
    n

    -R2\right)k\left(S

    (2)
    n

    \right)m-2k

    ,

    and

    (2m)
    S
    n

    =

    (2)
    \left(S
    n

    \right)m+

    \left\lfloorm/2\right\rfloor
    \sum
    k=1
    1
    2k

    \binom{m}{2k}\binom{2k}{k}

    (4)
    \left(S
    n
    (2)
    -\left(S
    n

    \right)2\right)k\left(S

    (2)
    n

    \right)m-2k

    ,

    where

    m

    is a positive integer less than

    n

    .

    If

    L

    is the distance from an arbitrary point in the plane to the centroid of a regular

    n

    -gon with circumradius

    R

    , then[3]
    n
    \sum
    i=1
    2m
    d
    i

    =nl(\left(R2+L2\right)m+

    \left\lfloorm/2\right\rfloor
    \sum
    k=1

    \binom{m}{2k}\binom{2k}{k}R2kL2k\left(R2+L2\right)m-2kr)

    ,where

    m

    = 1, 2, …,

    n-1

    .

    Interior points

    For a regular n-gon, the sum of the perpendicular distances from any interior point to the n sides is n times the apothem[4] (the apothem being the distance from the center to any side). This is a generalization of Viviani's theorem for the n = 3 case.[5] [6]

    Circumradius

    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=

    s
    2
    \sin\left(\pi
    n
    \right)

    =

    a
    \cos\left(\pi\right)
    n

    ,a=

    s
    2
    \tan\left(\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.[4]

    The sum of the squared distances from the vertices of a regular n-gon to any point on its circumcircle equals 2nR2 where R is the circumradius.[4]

    The sum of the squared distances from the midpoints of the sides of a regular n-gon to any point on the circumcircle is 2nR2ns2, where s is the side length and R is the circumradius.[4]

    If

    di

    are the distances from the vertices of a regular

    n

    -gon to any point on its circumcircle, then [3]
    n
    3l(\sum
    i=1
    2r)
    d
    i

    2=2n

    n
    \sum
    i=1
    4
    d
    i
    .

    Dissections

    Coxeter states that every zonogon (a 2m-gon whose opposite sides are parallel and of equal length) can be dissected into

    \tbinom{m}{2}

    or parallelograms.These tilings are contained as subsets of vertices, edges and faces in orthogonal projections m-cubes.[7] In particular, this is true for any regular polygon with an even number of sides, in which case the parallelograms are all rhombi.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[8] [9]

    A=\tfrac{1}{2}nsa=\tfrac{1}{2}pa=\tfrac{1}{4}ns2\cot\left(\tfrac{\pi}{n}\right)=na2\tan\left(\tfrac{\pi}{n}\right)=\tfrac{1}{2}nR2\sin\left(\tfrac{2\pi}{n}\right)

    For regular polygons with side s = 1, circumradius R = 1, or apothem a = 1, this produces the following table:[10] (Since

    \cotx1/x

    as

    x0

    , the area when

    s=1

    tends to

    n2/4\pi

    as

    n

    grows large.)
    Number
    of sides
    Area when side s = 1Area when circumradius R = 1Area when apothem a = 1
    ExactApproximationExactApproximationRelative to
    circumcirclearea
    ExactApproximationRelative to
    incirclearea
    n

    \tfrac{n}{4}\cot\left(\tfrac{\pi}{n}\right)

    \tfrac{n}{2}\sin\left(\tfrac{2\pi}{n}\right)

    \tfrac{n}{2\pi}\sin\left(\tfrac{2\pi}{n}\right)

    n\tan\left(\tfrac{\pi}{n}\right)

    \tfrac{n}{\pi}\tan\left(\tfrac{\pi}{n}\right)

    30.4330127021.299038105 0.41349667145.196152424 1.653986686
    41 1.0000000002 2.000000000 0.63661977224 4.000000000 1.273239544
    5 1.7204774012.377641291 0.7568267288 3.632712640 1.156328347
    62.5980762112.598076211 0.82699334283.464101616 1.102657791
    73.6339124442.736410189 0.87102641573.371022333 1.073029735
    84.8284271252.828427125 0.90031631603.313708500 1.054786175
    96.1818241942.892544244 0.92072542903.275732109 1.042697914
    10 7.6942088432.938926262 0.9354892840 3.249196963 1.034251515
    119.3656399072.973524496 0.94650224403.229891423 1.028106371
    12 11.196152423 3.000000000 0.95492965863.215390309 1.023490523
    1313.185768333.020700617 0.96151886943.204212220 1.019932427
    1415.334501943.037186175 0.96676638593.195408642 1.017130161
    1517.64236291 3.050524822 0.97101220883.188348426 1.014882824
    16 20.10935797 3.061467460 0.97449535843.182597878 1.013052368
    1722.735491903.070554163 0.97738774563.177850752 1.011541311
    1825.520768193.078181290 0.97981553613.173885653 1.010279181
    1928.465189433.084644958 0.98187298543.170539238 1.009213984
    2031.56875757 3.090169944 0.98363164303.167688806 1.008306663
    100795.51289883.139525977 0.99934215653.142626605 1.000329117
    100079577.209753.141571983 0.99999342003.141602989 1.000003290
    10,0007957746.8933.141592448 0.99999993453.141592757 1.000000033
    1,000,000795774715453.141592654 1.0000000003.141592654 1.000000000

    Of all n-gons with a given perimeter, the one with the largest area is regular.[11]

    Constructible polygon

    See main article: Constructible polygon.

    Some regular polygons are easy to construct with compass and straightedge; other regular polygons are not constructible at all.The ancient Greek mathematicians knew how to construct a regular polygon with 3, 4, or 5 sides, and they knew how to construct a regular polygon with double the number of sides of a given regular polygon.[12] This led to the question being posed: is it possible to construct all regular n-gons with compass and straightedge? If not, which n-gons are constructible and which are not?

    Carl Friedrich Gauss proved the constructibility of the regular 17-gon in 1796. Five years later, he developed the theory of Gaussian periods in his Disquisitiones Arithmeticae. This theory allowed him to formulate a sufficient condition for the constructibility of regular polygons:

    A regular n-gon can be constructed with compass and straightedge if n is the product of a power of 2 and any number of distinct Fermat primes (including none).

    (A Fermat prime is a prime number of the form

    \left(2n\right)
    2

    +1.

    ) Gauss stated without proof that this condition was also necessary, but never published his proof. A full proof of necessity was given by Pierre Wantzel in 1837. The result is known as the Gauss–Wantzel theorem.

    Equivalently, a regular n-gon is constructible if and only if the cosine of its common angle is a constructible number—that is, can be written in terms of the four basic arithmetic operations and the extraction of square roots.

    Regular skew polygons

    A regular skew polygon in 3-space can be seen as nonplanar paths zig-zagging between two parallel planes, defined as the side-edges of a uniform antiprism. All edges and internal angles are equal.

    More generally regular skew polygons can be defined in n-space. Examples include the Petrie polygons, polygonal paths of edges that divide a regular polytope into two halves, and seen as a regular polygon in orthogonal projection.

    In the infinite limit regular skew polygons become skew apeirogons.

    Regular star polygons

    Regular star polygons
    Above:2 < 2q < p, gcd(p, q) = 1
    Abovestyle:font-size: 14px;
    Label1:Schläfli symbol
    Label2:Vertices and Edges
    Data2:p
    Label3:Density
    Data3:q
    Label4:Coxeter diagram
    Label5:Symmetry group
    Data5:Dihedral (Dp)
    Label6:Dual polygon
    Data6:Self-dual
    Label7:Internal angle
    (degrees)
    Data7:
    180-360q
    p
    [13]

    A non-convex regular polygon is a regular star polygon. The most common example is the pentagram, which has the same vertices as a pentagon, but connects alternating vertices.

    For an n-sided star polygon, the Schläfli symbol is modified to indicate the density or "starriness" m of the polygon, as . If m is 2, for example, then every second point is joined. If m is 3, then every third point is joined. The boundary of the polygon winds around the center m times.

    The (non-degenerate) regular stars of up to 12 sides are:

    m and n must be coprime, or the figure will degenerate.

    The degenerate regular stars of up to 12 sides are:

    Depending on the precise derivation of the Schläfli symbol, opinions differ as to the nature of the degenerate figure. For example, may be treated in either of two ways:

    Duality of regular polygons

    All regular polygons are self-dual to congruency, and for odd n they are self-dual to identity.

    In addition, the regular star figures (compounds), being composed of regular polygons, are also self-dual.

    Regular polygons as faces of polyhedra

    A uniform polyhedron has regular polygons as faces, such that for every two vertices there is an isometry mapping one into the other (just as there is for a regular polygon).

    A quasiregular polyhedron is a uniform polyhedron which has just two kinds of face alternating around each vertex.

    A regular polyhedron is a uniform polyhedron which has just one kind of face.

    The remaining (non-uniform) convex polyhedra with regular faces are known as the Johnson solids.

    A polyhedron having regular triangles as faces is called a deltahedron.

    See also

    References

    Memoire sur les polygones et polyèdres. J. de l'École Polytechnique 9 (1810), pp. 16–48.

    External links

    Notes and References

    1. Hwa. Young Lee. 2017. Origami-Constructible Numbers. MA thesis . University of Georgia. 55–59.
    2. Park, Poo-Sung. "Regular polytope distances", Forum Geometricorum 16, 2016, 227-232. http://forumgeom.fau.edu/FG2016volume16/FG201627.pdf
    3. Meskhishvili . Mamuka. 2020. Cyclic Averages of Regular Polygons and Platonic Solids . Communications in Mathematics and Applications. 11. 335–355.
    4. Johnson, Roger A., Advanced Euclidean Geometry, Dover Publ., 2007 (orig. 1929).
    5. Pickover, Clifford A, The Math Book, Sterling, 2009: p. 150
    6. Chen, Zhibo, and Liang, Tian. "The converse of Viviani's theorem", The College Mathematics Journal 37(5), 2006, pp. 390–391.
    7. [Coxeter]
    8. Web site: Math Open Reference . 4 Feb 2014.
    9. Web site: Mathwords.
    10. Results for R = 1 and a = 1 obtained with Maple, using function definition:f := proc (n)options operator, arrow;[[convert(1/4*n*cot(Pi/n), radical), convert(1/4*n*cot(Pi/n), float)], [convert(1/2*n*sin(2*Pi/n), radical), convert(1/2*n*sin(2*Pi/n), float), convert(1/2*n*sin(2*Pi/n)/Pi, float)], [convert(n*tan(Pi/n), radical), convert(n*tan(Pi/n), float), convert(n*tan(Pi/n)/Pi, float)]]end procThe expressions for n = 16 are obtained by twice applying the tangent half-angle formula to tan(π/4)
    11. Chakerian, G.D. "A Distorted View of Geometry." Ch. 7 in Mathematical Plums (R. Honsberger, editor). Washington, DC: Mathematical Association of America, 1979: 147.
    12. Bold, Benjamin. Famous Problems of Geometry and How to Solve Them, Dover Publications, 1982 (orig. 1969).
    13. Book: Kappraff, Jay . Beyond measure: a guided tour through nature, myth, and number . World Scientific . 2002 . 258 . 978-981-02-4702-7 .
    14. http://www.math.washington.edu/~grunbaum/Your%20polyhedra-my%20polyhedra.pdf Are Your Polyhedra the Same as My Polyhedra?
    15. Regular polytopes, p.95
    16. Coxeter, The Densities of the Regular Polytopes II, 1932, p.53