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Symmetry (geometry)

March 04, 2023

In geometry, an object has symmetry if there is an operation or transformation (such as translation, scaling, rotation or reflection) that maps the figure/object onto itself (i.e., the object has an invariance under the transform).[1] Thus, a symmetry can be thought of as an immunity to change.[2] For instance, a circle rotated about its center will have the same shape and size as the original circle, as all points before and after the transform would be indistinguishable. A circle is thus said to be symmetric under rotation or to have rotational symmetry. If the isometry is the reflection of a plane figure about a line, then the figure is said to have reflectional symmetry or line symmetry;[3] it is also possible for a figure/object to have more than one line of symmetry.[4]

A drawing of a butterfly with bilateral symmetry, with left and right sides as mirror images of each other.

The types of symmetries that are possible for a geometric object depend on the set of geometric transforms available, and on what object properties should remain unchanged after a transformation. Because the composition of two transforms is also a transform and every transform has, by definition, an inverse transform that undoes it, the set of transforms under which an object is symmetric form a mathematical group, the symmetry group of the object.[5]

Euclidean symmetries in general

The most common group of transforms applied to objects are termed the Euclidean group of "isometries", which are distance-preserving transformations in space commonly referred to as two-dimensional or three-dimensional (i.e., in plane geometry or solid geometry Euclidean spaces). These isometries consist of reflections, rotations, translations, and combinations of these basic operations.[6] Under an isometric transformation, a geometric object is said to be symmetric if, after transformation, the object is indistinguishable from the object before the transformation.[7] A geometric object is typically symmetric only under a subset or "subgroup" of all isometries. The kinds of isometry subgroups are described below, followed by other kinds of transform groups, and by the types of object invariance that are possible in geometry.

By the Cartan–Dieudonné theorem, an orthogonal transformation in n-dimensional space can be represented by the composition of at most n reflections.

Basic isometries by dimension
1D 2D 3D 4D
Reflections Point Affine Point Affine Point Affine Point Affine
1 Reflection Reflection Reflection Reflection
2 Translation Rotation Translation Rotation Translation Rotation Translation
3 Transflection Rotoreflection Transflection Rotoreflection Transflection
4 Rotary translation Double rotation Rotary translation
5 Rotary transflection

Reflectional symmetry

Main article: Reflectional symmetry

Reflectional symmetry, linear symmetry, mirror symmetry, mirror-image symmetry, or bilateral symmetry is symmetry with respect to reflection.[8]

In one dimension, there is a point of symmetry about which reflection takes place; in two dimensions, there is an axis of symmetry (a.k.a., line of symmetry), and in three dimensions there is a plane of symmetry.[3][9] An object or figure for which every point has a one-to-one mapping onto another, equidistant from and on opposite sides of a common plane is called mirror symmetric (for more, see mirror image).

The axis of symmetry of a two-dimensional figure is a line such that, if a perpendicular is constructed, any two points lying on the perpendicular at equal distances from the axis of symmetry are identical. Another way to think about it is that if the shape were to be folded in half over the axis, the two halves would be identical as mirror images of each other. For example. a square has four axes of symmetry, because there are four different ways to fold it and have the edges match each other. Another example would be that of a circle, which has infinitely many axes of symmetry passing through its center for the same reason.[10]

If the letter T is reflected along a vertical axis, it appears the same. This is sometimes called vertical symmetry. Thus one can describe this phenomenon unambiguously by saying that "T has a vertical symmetry axis", or that "T has left-right symmetry".

The triangles with reflection symmetry are isosceles, the quadrilaterals with this symmetry are kites and isosceles trapezoids.[11]

For each line or plane of reflection, the symmetry group is isomorphic with Cs (see point groups in three dimensions for more), one of the three types of order two (involutions), hence algebraically isomorphic to C2. The fundamental domain is a half-plane or half-space.[12]

Point reflection and other involutive isometries

 
In 2 dimensions, a point reflection is a 180 degree rotation.
Main article: Point reflection

Reflection symmetry can be generalized to other isometries of m-dimensional space which are involutions, such as

(x1, ..., xm) ↦ (−x1, ..., −xk, xk+1, ..., xm)

in a certain system of Cartesian coordinates. This reflects the space along an (mk)-dimensional affine subspace.[13] If k = m, then such a transformation is known as a point reflection, or an inversion through a point. On the plane (m = 2), a point reflection is the same as a half-turn (180°) rotation; see below. Antipodal symmetry is an alternative name for a point reflection symmetry through the origin.[14]

Such a "reflection" preserves orientation if and only if k is an even number.[15] This implies that for m = 3 (as well as for other odd m), a point reflection changes the orientation of the space, like a mirror-image symmetry. That explains why in physics, the term P-symmetry (P stands for parity) is used for both point reflection and mirror symmetry. Since a point reflection in three dimensions changes a left-handed coordinate system into a right-handed coordinate system, symmetry under a point reflection is also called a left-right symmetry.[16]

Rotational symmetry

Main article: Rotational symmetry
 
The triskelion has 3-fold rotational symmetry.

Rotational symmetry is symmetry with respect to some or all rotations in m-dimensional Euclidean space. Rotations are direct isometries, which are isometries that preserve orientation.[17] Therefore, a symmetry group of rotational symmetry is a subgroup of the special Euclidean group E+(m).

Symmetry with respect to all rotations about all points implies translational symmetry with respect to all translations (because translations are compositions of rotations about distinct points),[18] and the symmetry group is the whole E+(m). This does not apply for objects because it makes space homogeneous, but it may apply for physical laws.

For symmetry with respect to rotations about a point, one can take that point as origin. These rotations form the special orthogonal group SO(m), which can be represented by the group of m × m orthogonal matrices with determinant 1. For m = 3, this is the rotation group SO(3).[19]

Phrased slightly differently, the rotation group of an object is the symmetry group within E+(m), the group of rigid motions;[20] that is, the intersection of the full symmetry group and the group of rigid motions. For chiral objects, it is the same as the full symmetry group.

Laws of physics are SO(3)-invariant if they do not distinguish different directions in space. Because of Noether's theorem, rotational symmetry of a physical system is equivalent to the angular momentum conservation law.[21] For more, see rotational invariance.

Translational symmetry

 
A frieze pattern with translational symmetry
Main article: Translational symmetry

Translational symmetry leaves an object invariant under a discrete or continuous group of translations  .[22] The illustration on the right shows four congruent footprints generated by translations along the arrow. If the line of footprints were to extend to infinity in both directions, then they would have a discrete translational symmetry; any translation that mapped one footprint onto another would leave the whole line unchanged.

Glide reflection symmetry

 
A frieze pattern with glide reflection symmetry
Main article: Glide reflection

In 2D, a glide reflection symmetry (also called a glide plane symmetry in 3D, and a transflection in general) means that a reflection in a line or plane combined with a translation along the line or in the plane, results in the same object (such as in the case of footprints).[2][23] The composition of two glide reflections results in a translation symmetry with twice the translation vector. The symmetry group comprising glide reflections and associated translations is the frieze group p11g, and is isomorphic with the infinite cyclic group Z.

Rotoreflection symmetry

 
A pentagonal antiprism with marked edges shows rotoreflectional symmetry, with an order of 10.
Main article: improper rotation

In 3D, a rotary reflection, rotoreflection or improper rotation is a rotation about an axis combined with reflection in a plane perpendicular to that axis.[24] The symmetry groups associated with rotoreflections include:

  • if the rotation angle has no common divisor with 360°, the symmetry group is not discrete.
  • if the rotoreflection has a 2n-fold rotation angle (angle of 180°/n), the symmetry group is S2n of order 2n (not to be confused with symmetric groups, for which the same notation is used; the abstract group is C2n). A special case is n = 1, an inversion, because it does not depend on the axis and the plane. It is characterized by just the point of inversion.
  • The group Cnh (angle of 360°/n); for odd n, this is generated by a single symmetry, and the abstract group is C2n, for even n. This is not a basic symmetry but a combination.

For more, see point groups in three dimensions.

Helical symmetry

See also: Screw axis

In 3D geometry and higher, a screw axis (or rotary translation) is a combination of a rotation and a translation along the rotation axis.[25]

Helical symmetry is the kind of symmetry seen in everyday objects such as springs, Slinky toys, drill bits, and augers. The concept of helical symmetry can be visualized as the tracing in three-dimensional space that results from rotating an object at a constant angular speed, while simultaneously translating at a constant linear speed along its axis of rotation. At any point in time, these two motions combine to give a coiling angle that helps define the properties of the traced helix.[26] When the tracing object rotates quickly and translates slowly, the coiling angle will be close to 0°. Conversely, if the object rotates slowly and translates quickly, the coiling angle will approach 90°.

 
A continuous helix

Three main classes of helical symmetry can be distinguished, based on the interplay of the angle of coiling and translation symmetries along the axis:

 
A regular skew-apeirogon has a discrete (3-fold here) screw-axis symmetry, drawn in perspective.
 
The Boerdijk–Coxeter helix, constructed by augmented regular tetrahedra, is an example of a screw axis symmetry that is nonperiodic.
  • Infinite helical symmetry: If there are no distinguishing features along the length of a helix or helix-like object, the object will have infinite symmetry much like that of a circle, but with the additional requirement of translation along the long axis of the object—to return it to its original appearance.[27] A helix-like object is one that has at every point the regular angle of coiling of a helix, but which can also have a cross section of indefinitely high complexity, provided only that precisely the same cross section exists (usually after a rotation) at every point along the length of the object. Simple examples include evenly coiled springs, slinkies, drill bits, and augers. Stated more precisely, an object has infinite helical symmetries if for any small rotation of the object around its central axis, there exists a point nearby (the translation distance) on that axis at which the object will appear exactly as it did before. It is this infinite helical symmetry that gives rise to the curious illusion of movement along the length of an auger or screw bit that is being rotated. It also provides the mechanically useful ability of such devices to move materials along their length, provided that they are combined with a force such as gravity or friction that allows the materials to resist simply rotating along with the drill or auger.
  • n-fold helical symmetry: If the requirement that every cross section of the helical object be identical is relaxed, then additional lesser helical symmetries would become possible. For example, the cross section of the helical object may change, but may still repeat itself in a regular fashion along the axis of the helical object. Consequently, objects of this type will exhibit a symmetry after a rotation by some fixed angle θ and a translation by some fixed distance, but will not in general be invariant for any rotation angle. If the angle of rotation at which the symmetry occurs divides evenly into a full circle (360°), then the result is the helical equivalent of a regular polygon. This case is called n-fold helical symmetry, where n = 360° (such as the case of a double helix). This concept can be further generalized to include cases where   is a multiple of 360° – that is, the cycle does eventually repeat, but only after more than one full rotation of the helical object.
  • Non-repeating helical symmetry: This is the case in which the angle of rotation θ required to observe the symmetry is irrational. The angle of rotation never repeats exactly, no matter how many times the helix is rotated. Such symmetries are created by using a non-repeating point group in two dimensions. DNA, with approximately 10.5 base pairs per turn, is an example of this type of non-repeating helical symmetry.[28]

Double rotation symmetry

 
A 4D clifford torus, stereographically projected into 3D, looks like a torus. A double rotation can be seen as a helical path.
See also: Rotations in 4-dimensional Euclidean space § Double rotations

In 4D, a double rotation symmetry can be generated as the composite of two orthogonal rotations.[29] It is similar to 3D screw axis which is the composite of a rotation and an orthogonal translation.

Non-isometric symmetries

A wider definition of geometric symmetry allows operations from a larger group than the Euclidean group of isometries. Examples of larger geometric symmetry groups are:

In Felix Klein's Erlangen program, each possible group of symmetries defines a geometry in which objects that are related by a member of the symmetry group are considered to be equivalent.[32] For example, the Euclidean group defines Euclidean geometry, whereas the group of Möbius transformations defines projective geometry.

Scale symmetry and fractals

 
A Julia set has scale symmetry

Scale symmetry means that if an object is expanded or reduced in size, the new object has the same properties as the original.[33] This self-similarity is seen in many natural structures such as cumulus clouds, lightning, ferns and coastlines, over a wide range of scales. It is generally not found in gravitationally bound structures, for example the shape of the legs of an elephant and a mouse (so-called allometric scaling). Similarly, if a soft wax candle were enlarged to the size of a tall tree, it would immediately collapse under its own weight.

A more subtle form of scale symmetry is demonstrated by fractals. As conceived by Benoît Mandelbrot, fractals are a mathematical concept in which the structure of a complex form looks similar at any degree of magnification,[34] well seen in the Mandelbrot set. A coast is an example of a naturally occurring fractal, since it retains similar-appearing complexity at every level from the view of a satellite to a microscopic examination of how the water laps up against individual grains of sand. The branching of trees, which enables small twigs to stand in for full trees in dioramas, is another example.

Because fractals can generate the appearance of patterns in nature, they have a beauty and familiarity not typically seen with mathematically generated functions. Fractals have also found a place in computer-generated movie effects, where their ability to create complex curves with fractal symmetries results in more realistic virtual worlds.

Abstract symmetry

Klein's view

With every geometry, Felix Klein associated an underlying group of symmetries. The hierarchy of geometries is thus mathematically represented as a hierarchy of these groups, and hierarchy of their invariants. For example, lengths, angles and areas are preserved with respect to the Euclidean group of symmetries, while only the incidence structure and the cross-ratio are preserved under the most general projective transformations. A concept of parallelism, which is preserved in affine geometry, is not meaningful in projective geometry. Then, by abstracting the underlying groups of symmetries from the geometries, the relationships between them can be re-established at the group level. Since the group of affine geometry is a subgroup of the group of projective geometry, any notion invariant in projective geometry is a priori meaningful in affine geometry; but not the other way round. If you add required symmetries, you have a more powerful theory but fewer concepts and theorems (which will be deeper and more general).

Thurston's view

William Thurston introduced a similar version of symmetries in geometry. A model geometry is a simply connected smooth manifold X together with a transitive action of a Lie group G on X with compact stabilizers. The Lie group can be thought of as the group of symmetries of the geometry.

A model geometry is called maximal if G is maximal among groups acting smoothly and transitively on X with compact stabilizers, i.e. if it is the maximal group of symmetries. Sometimes this condition is included in the definition of a model geometry.

A geometric structure on a manifold M is a diffeomorphism from M to X/Γ for some model geometry X, where Γ is a discrete subgroup of G acting freely on X. If a given manifold admits a geometric structure, then it admits one whose model is maximal.

A 3-dimensional model geometry X is relevant to the geometrization conjecture if it is maximal and if there is at least one compact manifold with a geometric structure modelled on X. Thurston classified the 8 model geometries satisfying these conditions; they are listed below and are sometimes called Thurston geometries. (There are also uncountably many model geometries without compact quotients.)

See also

References

  1. ^ Martin, G. (1996). Transformation Geometry: An Introduction to Symmetry. Springer. p. 28.
  2. ^ a b "Symmetry | Thinking about Geometry | Underground Mathematics". undergroundmathematics.org. Retrieved 2019-12-06.
  3. ^ a b "Symmetry - MathBitsNotebook(Geo - CCSS Math)". mathbitsnotebook.com. Retrieved 2019-12-06.
  4. ^ Freitag, Mark (2013). Mathematics for Elementary School Teachers: A Process Approach. Cengage Learning. p. 721.
  5. ^ Miller, Willard Jr. (1972). . New York: Academic Press. OCLC 589081. Archived from the original on 2010-02-17. Retrieved 2009-09-28.
  6. ^ "Higher Dimensional Group Theory". Archived from the original on 2012-07-23. Retrieved 2013-04-16.
  7. ^ "2.6 Reflection Symmetry". CK-12 Foundation. Retrieved 2019-12-06.
  8. ^ Weyl, Hermann (1982) [1952]. Symmetry. Princeton: Princeton University Press. ISBN 0-691-02374-3.
  9. ^ Cowin, Stephen C.; Doty, Stephen B. (2007). Tissue Mechanics. Springer. p. 152. ISBN 9780387368252.
  10. ^ Caldecott, Stratford (2009). Beauty for Truth's Sake: On the Re-enchantment of Education. Brazos Press. p. 70.
  11. ^ Bassarear, Tom (2011). Mathematics for Elementary School Teachers (5 ed.). Cengage Learning. p. 499.
  12. ^ Johnson, N. W. Johnson (2018). "11: Finite symmetry groups". Geometries and Transformations. Cambridge University Press.
  13. ^ Hertrich-Jeromin, Udo (2003). Introduction to Möbius Differential Geometry. Cambridge University Press.
  14. ^ Dieck, Tammo (2008). Algebraic Topology. European Mathematical Society. pp. 261. ISBN 9783037190487.
  15. ^ William H. Barker, Roger Howe Continuous Symmetry: From Euclid to Klein (Google eBook) American Mathematical Soc
  16. ^ W.M. Gibson & B.R. Pollard (1980). Symmetry principles in elementary particle physics. Cambridge University Press. pp. 120–122. ISBN 0-521-29964-0.
  17. ^ Vladimir G. Ivancevic, Tijana T. Ivancevic (2005) Natural Biodynamics World Scientific
  18. ^ Singer, David A. (1998). Geometry: Plane and Fancy. Springer Science & Business Media.
  19. ^ Joshi, A. W. (2007). Elements of Group Theory for Physicists. New Age International. pp. 111ff.
  20. ^ Hartshorne, Robin (2000). Geometry: Euclid and Beyond. Springer Science & Business Media.
  21. ^ Kosmann-Schwarzbach, Yvette (2010). The Noether theorems: Invariance and conservation laws in the twentieth century. Sources and Studies in the History of Mathematics and Physical Sciences. Springer-Verlag. ISBN 978-0-387-87867-6.
  22. ^ Stenger, Victor J. (2000) and Mahou Shiro (2007). Timeless Reality. Prometheus Books. Especially chapter 12. Nontechnical.
  23. ^ Martin, George E. (1982), Transformation Geometry: An Introduction to Symmetry, Undergraduate Texts in Mathematics, Springer, p. 64, ISBN 9780387906362.
  24. ^ Robert O. Gould, Steffen Borchardt-Ott (2011)Crystallography: An Introduction Springer Science & Business Media
  25. ^ Bottema, O, and B. Roth, Theoretical Kinematics, Dover Publications (September 1990)
  26. ^ George R. McGhee (2006) The Geometry of Evolution: Adaptive Landscapes and Theoretical Morphospaces Cambridge University Press p.64
  27. ^ Anna Ursyn(2012) Biologically-inspired Computing for the Arts: Scientific Data Through Graphics IGI Global Snippet p.209[clarification needed]
  28. ^ Sinden, Richard R. (1994). DNA structure and function. Gulf Professional Publishing. p. 101. ISBN 9780126457506.
  29. ^ Charles Howard Hinton (1906) The Fourth Dimension (Google eBook) S. Sonnenschein & Company p.223
  30. ^ H.S.M. Coxeter (1961,9) Introduction to Geometry, §5 Similarity in the Euclidean Plane, pp. 67–76, §7 Isometry and Similarity in Euclidean Space, pp 96–104, John Wiley & Sons.
  31. ^ William Thurston. Three-dimensional geometry and topology. Vol. 1. Edited by Silvio Levy. Princeton Mathematical Series, 35. Princeton University Press, Princeton, NJ, 1997. x+311 pp. ISBN 0-691-08304-5
  32. ^ Klein, Felix, 1872. "Vergleichende Betrachtungen über neuere geometrische Forschungen" ('A comparative review of recent researches in geometry'), Mathematische Annalen, 43 (1893) pp. 63–100 (Also: Gesammelte Abh. Vol. 1, Springer, 1921, pp. 460–497).
    An English translation by Mellen Haskell appeared in Bull. N. Y. Math. Soc 2 (1892–1893): 215–249.
  33. ^ Tian Yu Cao Conceptual Foundations of Quantum Field Theory Cambridge University Press p.154-155
  34. ^ Gouyet, Jean-François (1996). Physics and fractal structures. Paris/New York: Masson Springer. ISBN 978-0-387-94153-0.

External links

  • Dutch: Symmetry Around a Point in the Plane

March 04, 2023
symmetry, geometry, geometry, object, symmetry, there, operation, transformation, such, translation, scaling, rotation, reflection, that, maps, figure, object, onto, itself, object, invariance, under, transform, thus, symmetry, thought, immunity, change, insta. In geometry an object has symmetry if there is an operation or transformation such as translation scaling rotation or reflection that maps the figure object onto itself i e the object has an invariance under the transform 1 Thus a symmetry can be thought of as an immunity to change 2 For instance a circle rotated about its center will have the same shape and size as the original circle as all points before and after the transform would be indistinguishable A circle is thus said to be symmetric under rotation or to have rotational symmetry If the isometry is the reflection of a plane figure about a line then the figure is said to have reflectional symmetry or line symmetry 3 it is also possible for a figure object to have more than one line of symmetry 4 A drawing of a butterfly with bilateral symmetry with left and right sides as mirror images of each other The types of symmetries that are possible for a geometric object depend on the set of geometric transforms available and on what object properties should remain unchanged after a transformation Because the composition of two transforms is also a transform and every transform has by definition an inverse transform that undoes it the set of transforms under which an object is symmetric form a mathematical group the symmetry group of the object 5 Contents 1 Euclidean symmetries in general 2 Reflectional symmetry 3 Point reflection and other involutive isometries 4 Rotational symmetry 5 Translational symmetry 6 Glide reflection symmetry 6 1 Rotoreflection symmetry 7 Helical symmetry 8 Double rotation symmetry 9 Non isometric symmetries 10 Scale symmetry and fractals 11 Abstract symmetry 11 1 Klein s view 11 2 Thurston s view 12 See also 13 References 14 External linksEuclidean symmetries in general EditThe most common group of transforms applied to objects are termed the Euclidean group of isometries which are distance preserving transformations in space commonly referred to as two dimensional or three dimensional i e in plane geometry or solid geometry Euclidean spaces These isometries consist of reflections rotations translations and combinations of these basic operations 6 Under an isometric transformation a geometric object is said to be symmetric if after transformation the object is indistinguishable from the object before the transformation 7 A geometric object is typically symmetric only under a subset or subgroup of all isometries The kinds of isometry subgroups are described below followed by other kinds of transform groups and by the types of object invariance that are possible in geometry By the Cartan Dieudonne theorem an orthogonal transformation in n dimensional space can be represented by the composition of at most n reflections Basic isometries by dimension 1D 2D 3D 4DReflections Point Affine Point Affine Point Affine Point Affine1 Reflection Reflection Reflection Reflection2 Translation Rotation Translation Rotation Translation Rotation Translation3 Transflection Rotoreflection Transflection Rotoreflection Transflection4 Rotary translation Double rotation Rotary translation5 Rotary transflectionReflectional symmetry EditMain article Reflectional symmetry Reflectional symmetry linear symmetry mirror symmetry mirror image symmetry or bilateral symmetry is symmetry with respect to reflection 8 In one dimension there is a point of symmetry about which reflection takes place in two dimensions there is an axis of symmetry a k a line of symmetry and in three dimensions there is a plane of symmetry 3 9 An object or figure for which every point has a one to one mapping onto another equidistant from and on opposite sides of a common plane is called mirror symmetric for more see mirror image The axis of symmetry of a two dimensional figure is a line such that if a perpendicular is constructed any two points lying on the perpendicular at equal distances from the axis of symmetry are identical Another way to think about it is that if the shape were to be folded in half over the axis the two halves would be identical as mirror images of each other For example a square has four axes of symmetry because there are four different ways to fold it and have the edges match each other Another example would be that of a circle which has infinitely many axes of symmetry passing through its center for the same reason 10 If the letter T is reflected along a vertical axis it appears the same This is sometimes called vertical symmetry Thus one can describe this phenomenon unambiguously by saying that T has a vertical symmetry axis or that T has left right symmetry The triangles with reflection symmetry are isosceles the quadrilaterals with this symmetry are kites and isosceles trapezoids 11 For each line or plane of reflection the symmetry group is isomorphic with Cs see point groups in three dimensions for more one of the three types of order two involutions hence algebraically isomorphic to C2 The fundamental domain is a half plane or half space 12 Point reflection and other involutive isometries Edit In 2 dimensions a point reflection is a 180 degree rotation Main article Point reflection Reflection symmetry can be generalized to other isometries of m dimensional space which are involutions such as x1 xm x1 xk xk 1 xm in a certain system of Cartesian coordinates This reflects the space along an m k dimensional affine subspace 13 If k m then such a transformation is known as a point reflection or an inversion through a point On the plane m 2 a point reflection is the same as a half turn 180 rotation see below Antipodal symmetry is an alternative name for a point reflection symmetry through the origin 14 Such a reflection preserves orientation if and only if k is an even number 15 This implies that for m 3 as well as for other odd m a point reflection changes the orientation of the space like a mirror image symmetry That explains why in physics the term P symmetry P stands for parity is used for both point reflection and mirror symmetry Since a point reflection in three dimensions changes a left handed coordinate system into a right handed coordinate system symmetry under a point reflection is also called a left right symmetry 16 Rotational symmetry EditMain article Rotational symmetry The triskelion has 3 fold rotational symmetry Rotational symmetry is symmetry with respect to some or all rotations in m dimensional Euclidean space Rotations are direct isometries which are isometries that preserve orientation 17 Therefore a symmetry group of rotational symmetry is a subgroup of the special Euclidean group E m Symmetry with respect to all rotations about all points implies translational symmetry with respect to all translations because translations are compositions of rotations about distinct points 18 and the symmetry group is the whole E m This does not apply for objects because it makes space homogeneous but it may apply for physical laws For symmetry with respect to rotations about a point one can take that point as origin These rotations form the special orthogonal group SO m which can be represented by the group of m m orthogonal matrices with determinant 1 For m 3 this is the rotation group SO 3 19 Phrased slightly differently the rotation group of an object is the symmetry group within E m the group of rigid motions 20 that is the intersection of the full symmetry group and the group of rigid motions For chiral objects it is the same as the full symmetry group Laws of physics are SO 3 invariant if they do not distinguish different directions in space Because of Noether s theorem rotational symmetry of a physical system is equivalent to the angular momentum conservation law 21 For more see rotational invariance Translational symmetry Edit A frieze pattern with translational symmetry Main article Translational symmetry Translational symmetry leaves an object invariant under a discrete or continuous group of translations T a p p a displaystyle scriptstyle T a p p a 22 The illustration on the right shows four congruent footprints generated by translations along the arrow If the line of footprints were to extend to infinity in both directions then they would have a discrete translational symmetry any translation that mapped one footprint onto another would leave the whole line unchanged Glide reflection symmetry Edit A frieze pattern with glide reflection symmetry Main article Glide reflection In 2D a glide reflection symmetry also called a glide plane symmetry in 3D and a transflection in general means that a reflection in a line or plane combined with a translation along the line or in the plane results in the same object such as in the case of footprints 2 23 The composition of two glide reflections results in a translation symmetry with twice the translation vector The symmetry group comprising glide reflections and associated translations is the frieze group p11g and is isomorphic with the infinite cyclic group Z Rotoreflection symmetry Edit A pentagonal antiprism with marked edges shows rotoreflectional symmetry with an order of 10 Main article improper rotation In 3D a rotary reflection rotoreflection or improper rotation is a rotation about an axis combined with reflection in a plane perpendicular to that axis 24 The symmetry groups associated with rotoreflections include if the rotation angle has no common divisor with 360 the symmetry group is not discrete if the rotoreflection has a 2n fold rotation angle angle of 180 n the symmetry group is S2n of order 2n not to be confused with symmetric groups for which the same notation is used the abstract group is C2n A special case is n 1 an inversion because it does not depend on the axis and the plane It is characterized by just the point of inversion The group Cnh angle of 360 n for odd n this is generated by a single symmetry and the abstract group is C2n for even n This is not a basic symmetry but a combination For more see point groups in three dimensions Helical symmetry EditSee also Screw axis In 3D geometry and higher a screw axis or rotary translation is a combination of a rotation and a translation along the rotation axis 25 Helical symmetry is the kind of symmetry seen in everyday objects such as springs Slinky toys drill bits and augers The concept of helical symmetry can be visualized as the tracing in three dimensional space that results from rotating an object at a constant angular speed while simultaneously translating at a constant linear speed along its axis of rotation At any point in time these two motions combine to give a coiling angle that helps define the properties of the traced helix 26 When the tracing object rotates quickly and translates slowly the coiling angle will be close to 0 Conversely if the object rotates slowly and translates quickly the coiling angle will approach 90 A continuous helix Three main classes of helical symmetry can be distinguished based on the interplay of the angle of coiling and translation symmetries along the axis A regular skew apeirogon has a discrete 3 fold here screw axis symmetry drawn in perspective The Boerdijk Coxeter helix constructed by augmented regular tetrahedra is an example of a screw axis symmetry that is nonperiodic Infinite helical symmetry If there are no distinguishing features along the length of a helix or helix like object the object will have infinite symmetry much like that of a circle but with the additional requirement of translation along the long axis of the object to return it to its original appearance 27 A helix like object is one that has at every point the regular angle of coiling of a helix but which can also have a cross section of indefinitely high complexity provided only that precisely the same cross section exists usually after a rotation at every point along the length of the object Simple examples include evenly coiled springs slinkies drill bits and augers Stated more precisely an object has infinite helical symmetries if for any small rotation of the object around its central axis there exists a point nearby the translation distance on that axis at which the object will appear exactly as it did before It is this infinite helical symmetry that gives rise to the curious illusion of movement along the length of an auger or screw bit that is being rotated It also provides the mechanically useful ability of such devices to move materials along their length provided that they are combined with a force such as gravity or friction that allows the materials to resist simply rotating along with the drill or auger n fold helical symmetry If the requirement that every cross section of the helical object be identical is relaxed then additional lesser helical symmetries would become possible For example the cross section of the helical object may change but may still repeat itself in a regular fashion along the axis of the helical object Consequently objects of this type will exhibit a symmetry after a rotation by some fixed angle 8 and a translation by some fixed distance but will not in general be invariant for any rotation angle If the angle of rotation at which the symmetry occurs divides evenly into a full circle 360 then the result is the helical equivalent of a regular polygon This case is called n fold helical symmetry where n 360 such as the case of a double helix This concept can be further generalized to include cases where m 8 displaystyle scriptstyle m theta is a multiple of 360 that is the cycle does eventually repeat but only after more than one full rotation of the helical object Non repeating helical symmetry This is the case in which the angle of rotation 8 required to observe the symmetry is irrational The angle of rotation never repeats exactly no matter how many times the helix is rotated Such symmetries are created by using a non repeating point group in two dimensions DNA with approximately 10 5 base pairs per turn is an example of this type of non repeating helical symmetry 28 Double rotation symmetry Edit A 4D clifford torus stereographically projected into 3D looks like a torus A double rotation can be seen as a helical path See also Rotations in 4 dimensional Euclidean space Double rotations In 4D a double rotation symmetry can be generated as the composite of two orthogonal rotations 29 It is similar to 3D screw axis which is the composite of a rotation and an orthogonal translation Non isometric symmetries EditA wider definition of geometric symmetry allows operations from a larger group than the Euclidean group of isometries Examples of larger geometric symmetry groups are The group of similarity transformations 30 i e affine transformations represented by a matrix A that is a scalar times an orthogonal matrix Thus homothety is added self similarity is considered a symmetry The group of affine transformations represented by a matrix A with determinant 1 or 1 i e the transformations which preserve area 31 This adds e g oblique reflection symmetry The group of all bijective affine transformations The group of Mobius transformations which preserve cross ratios This adds e g inversive reflections such as circle reflection on the plane In Felix Klein s Erlangen program each possible group of symmetries defines a geometry in which objects that are related by a member of the symmetry group are considered to be equivalent 32 For example the Euclidean group defines Euclidean geometry whereas the group of Mobius transformations defines projective geometry Scale symmetry and fractals Edit A Julia set has scale symmetry Scale symmetry means that if an object is expanded or reduced in size the new object has the same properties as the original 33 This self similarity is seen in many natural structures such as cumulus clouds lightning ferns and coastlines over a wide range of scales It is generally not found in gravitationally bound structures for example the shape of the legs of an elephant and a mouse so called allometric scaling Similarly if a soft wax candle were enlarged to the size of a tall tree it would immediately collapse under its own weight A more subtle form of scale symmetry is demonstrated by fractals As conceived by Benoit Mandelbrot fractals are a mathematical concept in which the structure of a complex form looks similar at any degree of magnification 34 well seen in the Mandelbrot set A coast is an example of a naturally occurring fractal since it retains similar appearing complexity at every level from the view of a satellite to a microscopic examination of how the water laps up against individual grains of sand The branching of trees which enables small twigs to stand in for full trees in dioramas is another example Because fractals can generate the appearance of patterns in nature they have a beauty and familiarity not typically seen with mathematically generated functions Fractals have also found a place in computer generated movie effects where their ability to create complex curves with fractal symmetries results in more realistic virtual worlds Abstract symmetry EditKlein s view Edit With every geometry Felix Klein associated an underlying group of symmetries The hierarchy of geometries is thus mathematically represented as a hierarchy of these groups and hierarchy of their invariants For example lengths angles and areas are preserved with respect to the Euclidean group of symmetries while only the incidence structure and the cross ratio are preserved under the most general projective transformations A concept of parallelism which is preserved in affine geometry is not meaningful in projective geometry Then by abstracting the underlying groups of symmetries from the geometries the relationships between them can be re established at the group level Since the group of affine geometry is a subgroup of the group of projective geometry any notion invariant in projective geometry is a priori meaningful in affine geometry but not the other way round If you add required symmetries you have a more powerful theory but fewer concepts and theorems which will be deeper and more general Thurston s view Edit William Thurston introduced a similar version of symmetries in geometry A model geometry is a simply connected smooth manifold X together with a transitive action of a Lie group G on X with compact stabilizers The Lie group can be thought of as the group of symmetries of the geometry A model geometry is called maximal if G is maximal among groups acting smoothly and transitively on X with compact stabilizers i e if it is the maximal group of symmetries Sometimes this condition is included in the definition of a model geometry A geometric structure on a manifold M is a diffeomorphism from M to X G for some model geometry X where G is a discrete subgroup of G acting freely on X If a given manifold admits a geometric structure then it admits one whose model is maximal A 3 dimensional model geometry X is relevant to the geometrization conjecture if it is maximal and if there is at least one compact manifold with a geometric structure modelled on X Thurston classified the 8 model geometries satisfying these conditions they are listed below and are sometimes called Thurston geometries There are also uncountably many model geometries without compact quotients See also EditFractal Symmetric relationReferences Edit Martin G 1996 Transformation Geometry An Introduction to Symmetry Springer p 28 a b Symmetry Thinking about Geometry Underground Mathematics undergroundmathematics org Retrieved 2019 12 06 a b Symmetry MathBitsNotebook Geo CCSS Math mathbitsnotebook com Retrieved 2019 12 06 Freitag Mark 2013 Mathematics for Elementary School Teachers A Process Approach Cengage Learning p 721 Miller Willard Jr 1972 Symmetry Groups and Their Applications New York Academic Press OCLC 589081 Archived from the original on 2010 02 17 Retrieved 2009 09 28 Higher Dimensional Group Theory Archived from the original on 2012 07 23 Retrieved 2013 04 16 2 6 Reflection Symmetry CK 12 Foundation Retrieved 2019 12 06 Weyl Hermann 1982 1952 Symmetry Princeton Princeton University Press ISBN 0 691 02374 3 Cowin Stephen C Doty Stephen B 2007 Tissue Mechanics Springer p 152 ISBN 9780387368252 Caldecott Stratford 2009 Beauty for Truth s Sake On the Re enchantment of Education Brazos Press p 70 Bassarear Tom 2011 Mathematics for Elementary School Teachers 5 ed Cengage Learning p 499 Johnson N W Johnson 2018 11 Finite symmetry groups Geometries and Transformations Cambridge University Press Hertrich Jeromin Udo 2003 Introduction to Mobius Differential Geometry Cambridge University Press Dieck Tammo 2008 Algebraic Topology European Mathematical Society pp 261 ISBN 9783037190487 William H Barker Roger Howe Continuous Symmetry From Euclid to Klein Google eBook American Mathematical Soc W M Gibson amp B R Pollard 1980 Symmetry principles in elementary particle physics Cambridge University Press pp 120 122 ISBN 0 521 29964 0 Vladimir G Ivancevic Tijana T Ivancevic 2005 Natural Biodynamics World Scientific Singer David A 1998 Geometry Plane and Fancy Springer Science amp Business Media Joshi A W 2007 Elements of Group Theory for Physicists New Age International pp 111ff Hartshorne Robin 2000 Geometry Euclid and Beyond Springer Science amp Business Media Kosmann Schwarzbach Yvette 2010 The Noether theorems Invariance and conservation laws in the twentieth century Sources and Studies in the History of Mathematics and Physical Sciences Springer Verlag ISBN 978 0 387 87867 6 Stenger Victor J 2000 and Mahou Shiro 2007 Timeless Reality Prometheus Books Especially chapter 12 Nontechnical Martin George E 1982 Transformation Geometry An Introduction to Symmetry Undergraduate Texts in Mathematics Springer p 64 ISBN 9780387906362 Robert O Gould Steffen Borchardt Ott 2011 Crystallography An Introduction Springer Science amp Business Media Bottema O and B Roth Theoretical Kinematics Dover Publications September 1990 George R McGhee 2006 The Geometry of Evolution Adaptive Landscapes and Theoretical Morphospaces Cambridge University Press p 64 Anna Ursyn 2012 Biologically inspired Computing for the Arts Scientific Data Through Graphics IGI Global Snippet p 209 clarification needed Sinden Richard R 1994 DNA structure and function Gulf Professional Publishing p 101 ISBN 9780126457506 Charles Howard Hinton 1906 The Fourth Dimension Google eBook S Sonnenschein amp Company p 223 H S M Coxeter 1961 9 Introduction to Geometry 5 Similarity in the Euclidean Plane pp 67 76 7 Isometry and Similarity in Euclidean Space pp 96 104 John Wiley amp Sons William Thurston Three dimensional geometry and topology Vol 1 Edited by Silvio Levy Princeton Mathematical Series 35 Princeton University Press Princeton NJ 1997 x 311 pp ISBN 0 691 08304 5 Klein Felix 1872 Vergleichende Betrachtungen uber neuere geometrische Forschungen A comparative review of recent researches in geometry Mathematische Annalen 43 1893 pp 63 100 Also Gesammelte Abh Vol 1 Springer 1921 pp 460 497 An English translation by Mellen Haskell appeared in Bull N Y Math Soc 2 1892 1893 215 249 Tian Yu Cao Conceptual Foundations of Quantum Field Theory Cambridge University Press p 154 155 Gouyet Jean Francois 1996 Physics and fractal structures Paris New York Masson Springer ISBN 978 0 387 94153 0 External links EditCalotta A World of Symmetry Dutch Symmetry Around a Point in the Plane Retrieved from https en wikipedia org w index php title Symmetry geometry amp oldid 1128030693 Helical symmetry, wikipedia, wiki, book, books, library,

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