A regular hexagon is defined as a hexagon that is both
equilateral and
equiangular. Its
internal angle is one-third of a circle, equal to 120°. The
Schläfli symbol denotes this polygon as \{6\} . However, the regular hexagon can also be considered as cutting off the vertices of an equilateral triangle, which can also be denoted as \mathrm{t}\{3\} . A regular hexagon is
bicentric, meaning that it is both
cyclic (has a circumscribed circle) and
tangential (has an inscribed circle). The common length of the sides equals the radius of the
circumscribed circle or
circumcircle, which equals \tfrac{2}{\sqrt{3}} times the
apothem (radius of the
inscribed circle).
Measurement The longest diagonals of a regular hexagon, connecting diametrically opposite vertices, are twice the length of one side. From this it can be seen that a
triangle with a vertex at the center of the regular hexagon and sharing one side with the hexagon is
equilateral, and that the regular hexagon can be partitioned into six equilateral triangles. ;
r =
Inradius;
t = side length The maximal
diameter (which corresponds to the long
diagonal of the hexagon),
D, is twice the maximal radius or
circumradius,
R, which equals the side length,
t. The minimal diameter or the diameter of the
inscribed circle (separation of parallel sides, flat-to-flat distance, short diagonal or height when resting on a flat base),
d, is twice the minimal radius or
inradius,
r. The maxima and minima are related by the same factor: \begin{align} r &= \frac{d}{2} = \cos(30^\circ) R = \frac{\sqrt{3}}{2} R = \frac{\sqrt{3}}{2} t\\ d &= \frac{\sqrt{3}}{2} D\\ \end{align} The area of a regular hexagon \begin{align} A &= \frac{3\sqrt{3}}{2}R^2 &&= 3Rr = 2\sqrt{3} r^2 \\ &\approx 2.598 R^2 &&\approx 3.464 r^2\\ &= \frac{3\sqrt{3}}{8}D^2 &&= \frac{3}{4}Dd = \frac{\sqrt{3}}{2} d^2 \\ &\approx 0.6495 D^2 &&\approx 0.866 d^2. \end{align} For any regular
polygon, the area can also be expressed in terms of the
apothem a and the perimeter
p. For the regular hexagon these are given by
a =
r, and
p{} = 6R = 4r\sqrt{3}, so :\begin{align} A &= \frac{ap}{2} \\ &= \frac{r \cdot 4r\sqrt{3}}{2} = 2r^2\sqrt{3} \\ &\approx 3.464 r^2. \end{align} The regular hexagon fills the fraction \tfrac{3\sqrt{3}}{2\pi} \approx 0.8270 of its
circumscribed circle. If a regular hexagon has successive vertices A, B, C, D, E, F and if P is any point on the circumcircle between B and C, then . It follows from the ratio of
circumradius to
inradius that the height-to-width ratio of a regular hexagon is 1:1.1547005; that is, a hexagon with a long
diagonal of 1.0000000 will have a distance of 0.8660254 or cos(30°) between parallel sides.
Point in plane For an arbitrary point in the plane of a regular hexagon with circumradius R, whose distances to the centroid of the regular hexagon and its six vertices are L and d_i respectively, we have : d_1^2 + d_4^2 = d_2^2 + d_5^2 = d_3^2+ d_6^2= 2\left(R^2 + L^2\right), : d_1^2 + d_3^2+ d_5^2 = d_2^2 + d_4^2+ d_6^2 = 3\left(R^2 + L^2\right), : d_1^4 + d_3^4+ d_5^4 = d_2^4 + d_4^4+ d_6^4 = 3\left(\left(R^2 + L^2\right)^2 + 2 R^2 L^2\right). If d_i are the distances from the vertices of a regular hexagon to any point on its circumcircle, then There are 16 subgroups. There are 8 up to isomorphism: itself (D6), 2 dihedral: (D3, D2), 4
cyclic: (Z6, Z3, Z2, Z1) and the trivial (e) These symmetries express nine distinct symmetries of a regular hexagon.
John Conway labels these by a letter and group order.
r12 is full symmetry, and
a1 is no symmetry.
p6, an
isogonal hexagon constructed by three mirrors can alternate long and short edges, and
d6, an
isotoxal hexagon constructed with equal edge lengths, but vertices alternating two different internal angles. These two forms are
duals of each other and have half the symmetry order of the regular hexagon. The
i4 forms are regular hexagons flattened or stretched along one symmetry direction. It can be seen as an
elongated rhombus, while
d2 and
p2 can be seen as horizontally and vertically elongated
kites.
g2 hexagons, with opposite sides parallel are also called hexagonal
parallelogons. Each subgroup symmetry allows one or more degrees of freedom for irregular forms. Only the
g6 subgroup has no degrees of freedom but can be seen as
directed edges. Hexagons of symmetry
g2,
i4, and
r12, as
parallelogons can tessellate the Euclidean plane by translation. Other
hexagon shapes can tile the plane with different orientations. The 6 roots of the
simple Lie group A2, represented by a
Dynkin diagram , are in a regular hexagonal pattern. The two simple roots have a 120° angle between them. The 12 roots of the
Exceptional Lie group G2, represented by a
Dynkin diagram are also in a hexagonal pattern. The two simple roots of two lengths have a 150° angle between them.
Tessellations Like
squares and
equilateral triangles, regular hexagons fit together without any gaps to
tile the plane (three hexagons meeting at every vertex), and so are useful for constructing
tessellations. The cells of a
beehive honeycomb are hexagonal for this reason and because the shape makes efficient use of space and building materials. The
Voronoi diagram of a regular triangular lattice is the honeycomb tessellation of hexagons. == Dissection==