Reflection symmetry
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In mathematics, reflection symmetry, line symmetry, mirror symmetry, or mirror-image symmetry is symmetry with respect to a reflection. That is, a figure which does not change upon undergoing a reflection has reflectional symmetry.
In two-dimensional space, there is a line/axis of symmetry, in three-dimensional space, there is a plane of symmetry. An object or figure which is indistinguishable from its transformed image is called mirror symmetric.
Symmetric function
In formal terms, a
The symmetric function of a two-dimensional figure is a line such that, for each perpendicular constructed, if the perpendicular intersects the figure at a distance 'd' from the axis along the perpendicular, then there exists another intersection of the shape and the perpendicular at the same distance 'd' from the axis, in the opposite direction along the perpendicular.
Another way to think about the symmetric function is that if the shape were to be folded in half over the axis, the two halves would be identical: the two halves are each other's mirror images.[1] Thus, a square has four axes of symmetry because there are four different ways to fold it and have the edges all match. A circle has infinitely many axes of symmetry, while a cone and sphere have infinitely many planes of symmetry.
Symmetric geometrical shapes
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| isosceles trapezoid and kite | |
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| Hexagons | |
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| octagons | |
In 3D, the cube in which the plane can configure in all of the three axes that can reflect the cube has 9 planes of reflective symmetry.[3]
Advanced types of reflection symmetry
For more general types of reflection there are correspondingly more general types of reflection symmetry. For example:
- with respect to a non-isometric affine involution (an oblique reflection in a line, plane, etc.)
- with respect to circle inversion.
In nature
Animals that are bilaterally symmetric have reflection symmetry around the sagittal plane, which divides the body vertically into left and right halves, with one of each sense organ and limb pair on either side. Most animals are bilaterally symmetric, likely because this supports forward movement and streamlining.[4][5][6]
In architecture
Mirror symmetry is often used in
See also
- Patterns in nature
- Point reflection symmetry
- Coxeter group theory about Reflection groups in Euclidean space
- Rotational symmetry (different type of symmetry)
- Chirality
References
- ^ a b Stewart, Ian (2001). What Shape is a Snowflake? Magical Numbers in Nature. Weidenfeld & Nicolson. p. 32.
- ISBN 0-393-04002-X.
- ^ O’Brien, David; McShane, Pauric; Thornton, Sean. "The Group of Symmetries of the Cube" (PDF). NUI Galway.
- ^ Valentine, James W. "Bilateria". AccessScience. Archived from the original on November 17, 2007. Retrieved May 29, 2013.
- PMID 16237677.
- ^ "Bilateral (left/right) symmetry". Berkeley. Retrieved June 14, 2014.
- ISBN 978-0-300-07615-8.
More accurate surveys indicate that the facade lacks a precise symmetry, but there can be little doubt that Alberti intended the composition of number and geometry to be regarded as perfect. The facade fits within a square of 60 Florentine braccia
- ^ Johnson, Anthony (2008). Solving Stonehenge: The New Key to an Ancient Enigma. Thames & Hudson.
- ^ Waters, Suzanne. "Palladianism". Royal Institution of British Architects. Retrieved October 29, 2015.
Bibliography
General
- Stewart, Ian (2001). What Shape is a Snowflake? Magical Numbers in Nature. Weidenfeld & Nicolson.
Advanced
- ISBN 0-691-02374-3.
