Symmetry combinations

This article discusses various symmetry Symmetry

Symmetry is a characteristic feature of geometrical [i] shapes, system [i]s, equation [i]s, and ...

combinations. In 2D, mirror-image symmetry in combination with n-fold rotational symmetry, with the center of rotational symmetry on the line of symmetry, implies mirror-image symmetry with respect to lines of reflection rotated by multiples of 180?/n, i.e. n reflection lines which are radially spaced evenly . The symmetry group is the dihedral group Dihedral group

In mathematics [i], the dihedral group of order [i] 2n is the abstract group of which one repr ...

of order 2n. For n > 2 an example is the n-sided regular polygon Polygon

A polygon is a closed [i] planar [i] path composed of a finite number of sequential ...

and various n-sided star polygon Star polygon

> [i] [i] ...

s, including complex ones, which are a combination of simple ones for a divisor of n; also we have the simple "star" of n radial line segments .

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This article discusses various symmetry Symmetry

Symmetry is a characteristic feature of geometrical [i] shapes, system [i]s, equation [i]s, and ...

combinations.

In 2D, mirror-image symmetry in combination with n-fold rotational symmetry, with the center of rotational symmetry on the line of symmetry, implies mirror-image symmetry with respect to lines of reflection rotated by multiples of 180°/n, i.e. n reflection lines which are radially spaced evenly . The symmetry group is the dihedral group Dihedral group

In mathematics [i], the dihedral group of order [i] 2n is the abstract group of which one repr ...

of order 2n. For n > 2 an example is the n-sided regular polygon Polygon

A polygon is a closed [i] planar [i] path composed of a finite number of sequential ...

and various n-sided star polygon Star polygon

> [i]
[i] ...

s, including complex ones, which are a combination of simple ones for a divisor of n; also we have the simple "star" of n radial line segments . Also multiple regular n-sided polygons with common center, differing by arbitrary rotations, as long as these rotation angles have mirror-image symmetry, e.g. two squares differing by a rotation angle of 10°, or three squares differing by two successive rotation angles of 10°.

Other examples:

n=2: rectangle Rectangle

In geometry [i], a rectangle is defined as a quadrilateral [i] where all four of its angles are right angle [i] ...

, rhombus Rhombus

In geometry [i], a rhombus is a quadrilateral [i] in which all of the sides are of equal length, i.e., i ...
n=5: regular Penrose tiling Penrose tiling

[Image:richert1a.jpg|320px|thumb|Artwork by Clark Richert, a/c 70" x 70"]] [i]

...

- infinite tiling, but no translational symmetry

Conversely, mirror-image symmetry with respect to two lines of reflection at an angle of 180°/n implies n-fold rotational symmetry .

In particular:

Mirror-image symmetry with respect to two perpendicular lines of reflection implies rotational symmetry at the point of intersection for an angle of 180°. The symmetry group is the Klein four-group Klein four-group

[i] Z2 × Z2, the [[direct product]...

. This applies e.g. for a rectangle Rectangle

In geometry [i], a rectangle is defined as a quadrilateral [i] where all four of its angles are right angle [i] ...

, a rhombus Rhombus

In geometry [i], a rhombus is a quadrilateral [i] in which all of the sides are of equal length, i.e., i ...

, and the letter H.
Mirror-image symmetry of a square with respect to the horizontal axis and to one diagonal, implies mirror-image symmetry with respect to the vertical axis and the other diagonal, and 4-fold rotational symmetry.

Mirror-image symmetry in combination with 2-fold rotational symmetry, with the point of symmetry not on the line of symmetry, implies an infinite sequence of alternating centers of symmetry and parallel lines of reflection, evenly spaced, with all these centers on a line perpendicular to the lines of reflection . It also implies translational symmetry with as translation vector twice the difference in position between adjacent centers. This is frieze group Frieze group

A frieze group is a mathematical concept to classify designs on two-dimensional surfaces which are repet...

nr. 6.

Translational symmetry can only be combined with 2-, 3-, 4-, and 6-fold rotational symmetry , see crystallographic restriction theorem Crystallographic restriction theorem

The crystallographic restriction theorem in its basic form is the observation that the rotation [i]al symmetries [i]...

. In these cases the translational symmetry applies along lines in 1, 3, 2, and 3 directions, respectively. This applies for 13 of the 17 wallpaper group Wallpaper group

A wallpaper group is a mathematical classification of a two-dimensional repetitive pattern, based on the...

s.

In the case of translational symmetry combined with 2-fold rotational symmetry, other centers of this symmetry can be found by translations by half the distances .

n-fold rotational symmetry with respect to two points of rotation implies translational symmetry.

In 3D we can distinguish a plane of reflection through the axis of rotational symmetry, and hence n of them, similar to the 2D case , perpendicular to it , and both . In the latter case there are n perpendicular 2-fold rotation axes in the n planes of reflection. If, instead, the 2-fold rotation axes are in between the planes of reflection, hence we have a 2n-fold rotation-reflection axis, this is D_nd; with only this 2n-fold rotation-reflection axis we have S_2n.

Also there may be no plane of reflection, but just an additional, perpendicular 2-fold axis of rotation, and hence n of them .

See also chirality, chirality , and rigid body.

Mirror-image symmetry in combination with translational symmetry

Mirror-image symmetry in combination with translational symmetry, with the translational vector not along the line or plane of reflection, implies that there are infinitely many parallel lines or planes of reflection, with a spacing such that one half of the translational vector, starting at one, ends at the next.

In 2D, with translation in one direction, this is freeze group 4, or in the case of additional symmetry, 6 or 7.

In 2D, with translation in two directions there are two cases:

the translation vectors can be chosen to be perpendicular, and the rectangle spanned by these can be positioned with the axes of reflection along two opposite sides and halfway

the second case concerns wallpaper group cm Wallpaper group

A wallpaper group is a mathematical classification of a two-dimensional repetitive pattern, based on the...

; one can choose different representations:

the translation vectors can be chosen symmetrically with respect to an axis of reflection; then they have equal magnitude and the rhombus spanned by these has axes of reflection along a diagonal and through the other two vertices
we can also choose one translation vector perpendicular to the axes of reflection, while they cross it at the ends and midway; then the other translation vector can be chosen such that it ends at the axis of reflection crossing the first translation vector midway; in that case the two span a parallelogram with one diagonal having equal length as each of one pair of sides with the axes of reflection through all vertices
one can consider a rectangle with one pair of sides perpendicular to the axes of reflection and the other pair of sides parallel to it; in that case the latter are not translation vectors; from a vertex to halfway a side of the first pair is the other translation vector; such a rectangle , reproduced by translation, fills the plane and forms a common tiling ; due to the symmetry, one half of it is a fundamental domain; this can e.g. be rectangular . If the bricks are vertically symmetric the brick's image without rotation represents another correspondence with the upper image, with the brick in the two strips in the center.

.

Group cm can also be described as a rectangular checkerboard Checkerboard

A checkerboard is a board on which American checkers [i] is played. ...

pattern, where the pattern of each of the two tiles is symmetric in, say, the horizontal direction, or looking at it differently a checkerboard pattern where the two tiles are each other's mirror image.

With additional reflection axes perpendicular to the other ones, we have cmm; in the case of the bricks this corresponds to homogeneous bricks, or, more generally, double symmetric ones.

Group cmm can be described as a checkerboard pattern of 2-fold rotational tiles and their mirror image, or looking at it differently a checkerboard pattern of two horizontally and vertically symmetric tiles.

Rotational symmetry of order 3 and/or 6 in combination with translational symmetry

Of course rotational symmetry of order 3 or more in combination with translational symmetry implies translational symmetry in two directions.

Rotational symmetry of order 3 at one center of rotation and order 2 at another one implies rotational symmetry of order 6 at some center of rotation.

In the case of rotational symmetry of order 6, the centers of rotation of order 3 are arranged in a honeycomb Honeycomb

A honeycomb is a mass of hexagon [i]al wax [i] cells built by honeybee [i]s in their nests to contain th ...

structure, and the centers of rotation of order 2 in little triangles around them, touching each other, and also forming hexagons, rotated 30° and a little smaller.

See also hexagonal lattice Hexagonal lattice

The hexagonal lattice or equilateral triangular lattice is one of the five 2D lattice [i] ...

.

Rotational symmetry of order 4 in combination with translational symmetry

Of course rotational symmetry of order 4 in combination with translational symmetry implies translational symmetry in two directions.

There are two different rotational centers of order 4, each in an upright square lattice, and together in a denser diagonal square lattice , each as many as there are translational cells. Also there is one kind of rotational center of order 2, there are as many of them as the other two together.

In the figures the two kinds of rotational centers of order 4 are distinguished by color , except in p4g, where the two kinds are each other's mirror image, both shown in green.

There is, of course, also translational symmetry with translations √2 times as large as the minimum, diagonally. Therefore the symmetries mentioned in the previous paragraph also apply in these larger translational squares. The two rotational centers of order 4 mentioned there are of the same kind in the larger squares, and the rotational centers midway on the sides are also of order 4.

Only in group p4g the properties really change when considering these larger, tilted squares: the lines of reflection, which were in diagonal direction, are horizontal and vertical relative to the larger squares, positioned at 1/4 and 3/4 of the square. The rotational centers midway on the sides of the larger squares are the mirror image of those in the corners and in the center.

In p4g there is a checkerboard Checkerboard

A checkerboard is a board on which American checkers [i] is played. ...

pattern of 4-fold rotational tiles and their mirror image, or looking at it differently a checkerboard pattern of horizontally and vertically symmetric tiles and their 90° rotated version. Note that neither applies for a plain checkerboard pattern of black and white tiles, this is group p4m .

See also square lattice Square lattice

The square lattice is one of the five 2D lattice [i] types. ...

.