bipyramid

{{multiple image

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| image1 = Triangular bipyramid.png

| image2 = Square bipyramid.png

| image3 = Pentagonale bipiramide.png

| footer = The triangular bipyramid, square bipyramid, and pentagonal bipyramid.

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A bipyramid is a polyhedron constructed by fusing two pyramids which share the same polygonal base;{{r|aarts}} a pyramid is in turn constructed by connecting each vertex of its base to a single new vertex (the apex) not lying in the plane of the base, for an {{nowrap|1={{mvar|n}}-}}gonal base forming {{mvar|n}} triangular faces in addition to the base face. An {{nowrap|1={{mvar|n}}-}}gonal bipyramid thus has {{math|2n}} faces, {{math|3n}} edges, and {{math|n + 2}} vertices. {{anchor|1=Right and oblique bipyramid}}More generally, a right pyramid is a pyramid where the apices are on the perpendicular line through the centroid of an arbitrary polygon or the incenter of a tangential polygon, depending on the source.{{efn|name=right pyramids}} Likewise, a right bipyramid is a polyhedron constructed by attaching two symmetrical right bipyramid bases; bipyramids whose apices are not on this line are called oblique bipyramids.{{r|polya}}

When the two pyramids are mirror images, the bipyramid is called symmetric. It is called regular if its base is a regular polygon.{{r|aarts}} When the base is a regular polygon and the apices are on the perpendicular line through its center (a regular right bipyramid) then all of its faces are isosceles triangles; sometimes the name bipyramid refers specifically to symmetric regular right bipyramids,{{r|montroll}} Examples of such bipyramids are the triangular bipyramid, octahedron (square bipyramid) and pentagonal bipyramid. If all their edges are equal in length, these shapes consist of equilateral triangle faces, making them deltahedra;{{r|trigg|uehara}} the triangular bipyramid and the pentagonal bipyramid are Johnson solids, and the regular octahedron is a Platonic solid.{{r|cromwell}}

File:Dual Cube-Octahedron.svg

The symmetric regular right bipyramids have prismatic symmetry, with dihedral symmetry group {{math|D_nh}} of order {{math|4n}}: they are unchanged when rotated {{math|{{sfrac|1|n}}}} of a turn around the axis of symmetry, reflected across any plane passing through both apices and a base vertex or both apices and the center of a base edge, or reflected across the mirror plane.{{r|fsz}} Because their faces are transitive under these symmetry transformations, they are isohedral.{{r|cpsb|mclean}} They are the dual polyhedra of prisms and the prisms are the dual of bipyramids as well; the bipyramids vertices correspond to the faces of the prism, and the edges between pairs of vertices of one correspond to the edges between pairs of faces of the other, and vice versa.{{r|sibley}} The prisms share the same symmetry as the bipyramids.{{r|king}} The regular octahedron is more symmetric still, as its base vertices and apices are indistinguishable and can be exchanged by reflections or rotations; the regular octahedron and its dual, the cube, have octahedral symmetry.{{r|armstrong}}

The volume of a symmetric bipyramid is

$$\backslash frac\{2\}\{3\}Bh,$$

where {{mvar|B}} is the area of the base and {{mvar|h}} the perpendicular distance from the base plane to either apex. In the case of a regular {{nowrap|1={{mvar|n}}-}}sided polygon with side length {{mvar|s}} and whose altitude is {{mvar|h}}, the volume of such a bipyramid is:

$$\backslash frac\{n\}\{6\}hs^2\; \backslash cot\; \backslash frac\{\backslash pi\}\{n\}.$$

{{multiple image

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| image1 = Concave quadrilateral bipyramid.png |caption1=A concave tetragonal bipyramid

| image2 = Asymmetric hexagonal bipyramid.png |caption2= An asymmetric hexagonal bipyramid

}}

A concave bipyramid has a concave polygon base, and one example is a concave tetragonal bipyramid or an irregular concave octahedron. A bipyramid with an arbitrary polygonal base could be considered a right bipyramid if the apices are on a line perpendicular to the base passing through the base's centroid.

An asymmetric bipyramid has apices which are not mirrored across the base plane; for a right bipyramid this only happens if each apex is a different distance from the base.

The dual of an asymmetric right {{mvar|n}}-gonal bipyramid is an {{mvar|n}}-gonal frustum.

A regular asymmetric right {{mvar|n}}-gonal bipyramid has symmetry group {{math|C_nv}}, of order {{math|2n}}.

File:EB1911 Crystallography Fig. 46 Ditetragonal Bipyramid.jpg

An isotoxal right (symmetric) di-{{mvar|n}}-gonal bipyramid is a right (symmetric) {{math|2n}}-gonal bipyramid with an isotoxal flat polygon base: its {{math|2n}} basal vertices are coplanar, but alternate in two radii.

All its faces are congruent scalene triangles, and it is isohedral. It can be seen as another type of a right symmetric di-{{mvar|n}}-gonal scalenohedron, with an isotoxal flat polygon base.

An isotoxal right (symmetric) di-{{mvar|n}}-gonal bipyramid has {{mvar|n}} two-fold rotation axes through opposite basal vertices, {{mvar|n}} reflection planes through opposite apical edges, an {{mvar|n}}-fold rotation axis through apices, a reflection plane through base, and an {{mvar|n}}-fold rotation-reflection axis through apices, representing symmetry group {{math|D_nh, [n,2], (*22n),}} of order {{math|4n}}. (The reflection about the base plane corresponds to the {{math|0°}} rotation-reflection. If {{mvar|n}} is even, then there is an inversion symmetry about the center, corresponding to the {{math|180°}} rotation-reflection.)

Example with {{math|1=2n = 2×3}}:

:An isotoxal right (symmetric) ditrigonal bipyramid has three similar vertical planes of symmetry, intersecting in a (vertical) {{math|3}}-fold rotation axis; perpendicular to them is a fourth plane of symmetry (horizontal); at the intersection of the three vertical planes with the horizontal plane are three similar (horizontal) {{math|2}}-fold rotation axes; there is no center of inversion symmetry,{{sfn|Spencer|1911|loc=6. Hexagonal system, rhombohedral division, ditrigonal bipyramidal class, p. 581 (p. 603 on Wikisource)}} but there is a center of symmetry: the intersection point of the four axes.

Example with {{math|1=2n = 2×4}}:

:An isotoxal right (symmetric) ditetragonal bipyramid has four vertical planes of symmetry of two kinds, intersecting in a (vertical) {{math|4}}-fold rotation axis; perpendicular to them is a fifth plane of symmetry (horizontal); at the intersection of the four vertical planes with the horizontal plane are four (horizontal) {{math|2}}-fold rotation axes of two kinds, each perpendicular to a plane of symmetry; two vertical planes bisect the angles between two horizontal axes; and there is a centre of inversion symmetry.{{sfn|Spencer|1911|loc=2. Tegragonal system, holosymmetric class, fig. 46, p. 577 (p. 599 on Wikisource)}}

Double example:

• The bipyramid with isotoxal {{math|2×2}}-gon base vertices {{mvar|U, U', V, V'}} and right symmetric apices {{mvar|A, A'}}$$\backslash begin\{alignat\}\{5\}$$

U &= (1,0,0), & \quad V &= (0,2,0), & \quad A &= (0,0,1), \\

U' &= (-1,0,0), & \quad V' &= (0,-2,0), & \quad A' &= (0,0,-1),

\end{alignat} has its faces isosceles. Indeed:

• Upper apical edge lengths:$$\backslash begin\{align\}$$

\overline{AU} &= \overline{AU'} = \sqrt{2} \,, \\[2pt]

\overline{AV} &= \overline{AV'} = \sqrt{5} \,;

\end{align}

• Base edge lengths: $$$$

\overline{UV} = \overline{VU'} = \overline{U'V'} = \overline{V'U} = \sqrt{5} \,;

• Lower apical edge lengths (equal to upper edge lengths):$$\backslash begin\{align\}$$

\overline{A'U} &= \overline{A'U'} = \sqrt{2} \,, \\[2pt]

\overline{A'V} &= \overline{A'V'} = \sqrt{5} \,.

\end{align}

• The bipyramid with same base vertices, but with right symmetric apices $$\backslash begin\{align\}$$

A &= (0,0,2), \\

A' &= (0,0,-2),

\end{align} also has its faces isosceles. Indeed:

• Upper apical edge lengths:$$\backslash begin\{align\}$$

\overline{AU} &= \overline{AU'} = \sqrt{5} \,, \\[2pt]

\overline{AV} &= \overline{AV'} = 2\sqrt{2} \,;

\end{align}

• Base edge length (equal to previous example): $$$$

\overline{UV} = \overline{VU'} = \overline{U'V'} = \overline{V'U} = \sqrt{5}\,;

• Lower apical edge lengths (equal to upper edge lengths):$$\backslash begin\{align\}$$

\overline{A'U} &= \overline{A'U'} = \sqrt{5}\,, \\[2pt]

\overline{A'V} &= \overline{A'V'} = 2\sqrt{2}\,.

\end{align}

File:EB1911 Crystallography Figs. 54 & 55 Orthorhombic Bipyramids.jpg

In crystallography, isotoxal right (symmetric) didigonal{{efn|The smallest geometric di-{{mvar|n}}-gonal bipyramids have eight faces, and are topologically identical to the regular octahedron. In this case ({{math|1=2n = 2×2}}):
an isotoxal right (symmetric) didigonal bipyramid is called a rhombic bipyramid, although all its faces are scalene triangles, because its flat polygon base is a rhombus.}} (8-faced), ditrigonal (12-faced), ditetragonal (16-faced), and dihexagonal (24-faced) bipyramids exist.{{cite web|url=http://www.tulane.edu/~sanelson/eens211/forms_zones_habit.htm|title=Crystal Form, Zones, Crystal Habit|website=Tulane.edu|access-date=16 September 2017}}

File:EB1911 Crystallography Fig. 68.—Scalenohedron.jpg

A scalenohedron is similar to a bipyramid; the difference is that the scalenohedra has a zig-zag pattern in the middle edges.{{r|kp}}

It has two apices and {{math|2n}} basal vertices, {{math|4n}} faces, and {{math|6n}} edges; it is topologically identical to a {{math|2n}}-gonal bipyramid, but its {{math|2n}} basal vertices alternate in two rings above and below the center.{{Cite web|date=2013-09-18|title=The 48 Special Crystal Forms|url=https://www.uwgb.edu/dutchs/symmetry/xlforms.htm|access-date=2020-11-18|archive-url=https://web.archive.org/web/20130918103121/https://www.uwgb.edu/dutchs/symmetry/xlforms.htm|archive-date=18 September 2013}}

All its faces are congruent scalene triangles, and it is isohedral. It can be seen as another type of a right symmetric di-{{mvar|n}}-gonal bipyramid, with a regular zigzag skew polygon base.

A regular right symmetric di-{{mvar|n}}-gonal scalenohedron has {{mvar|n}} two-fold rotation axes through opposite basal mid-edges, {{mvar|n}} reflection planes through opposite apical edges, an {{mvar|n}}-fold rotation axis through apices, and a {{math|2n}}-fold rotation-reflection axis through apices (about which {{math|1n}} rotations-reflections globally preserve the solid), representing symmetry group {{math|1=D_nv = D_nd, [2⁺,2n], (2*n),}} of order {{math|4n}}. (If {{mvar|n}} is odd, then there is an inversion symmetry about the center, corresponding to the {{math|180°}} rotation-reflection.)

Example with {{math|1=2n = 2×3}}:

:A regular right symmetric ditrigonal scalenohedron has three similar vertical planes of symmetry inclined to one another at {{math|60°}} and intersecting in a (vertical) {{math|3}}-fold rotation axis, three similar horizontal {{math|2}}-fold rotation axes, each perpendicular to a plane of symmetry, a center of inversion symmetry,{{sfn|Spencer|1911|loc=6. Hexagonal system, rhombohedral division, holosymmetric class, fig. 68, p. 580 (p. 602 on Wikisource)}} and a vertical {{math|6}}-fold rotation-reflection axis.

Example with {{math|1=2n = 2×2}}:

:A regular right symmetric didigonal scalenohedron has only one vertical and two horizontal {{math|2}}-fold rotation axes, two vertical planes of symmetry, which bisect the angles between the horizontal pair of axes, and a vertical {{math|4}}-fold rotation-reflection axis;{{sfn|Spencer|1911|p=2. Tetragonal system, scalenohedral class, fig. 51, p. 577 (p. 599 on Wikisource)}} it has no center of inversion symmetry.

File:EB1911 Crystallography Figs. 50 & 51.jpg

For at most two particular values of $z\_A\; =\; |z\_\{A\text{'}\}|,$ the faces of such a scalenohedron may be isosceles.

Double example:

• The scalenohedron with regular zigzag skew {{math|2×2}}-gon base vertices {{mvar|U, U', V, V'}} and right symmetric apices {{mvar|A, A'}}$$\backslash begin\{alignat\}\{5\}$$

U &= (3,0,2), & \quad V &= (0,3,-2), & \quad A &= (0,0,3), \\

U' &= (-3,0,2), & \quad V' &= (0,-3,-2), & \quad A' &= (0,0,-3),

\end{alignat} has its faces isosceles. Indeed:

• Upper apical edge lengths:$$\backslash begin\{align\}$$

\overline{AU} &= \overline{AU'} = \sqrt{10} \,, \\[2pt]

\overline{AV} &= \overline{AV'} = \sqrt{34} \,;

\end{align}

• Base edge length:$$$$

\overline{UV} = \overline{VU'} = \overline{U'V'} = \overline{V'U} = \sqrt{34} \,;

• Lower apical edge lengths (equal to upper edge lengths swapped):$$\backslash begin\{align\}$$

\overline{A'U} &= \overline{A'U'} = \sqrt{34} \,, \\[2pt]

\overline{A'V} &= \overline{A'V'} = \sqrt{10} \,.

\end{align}

• The scalenohedron with same base vertices, but with right symmetric apices$$\backslash begin\{align\}$$

A &= (0,0,7), \\

A' &= (0,0,-7),

\end{align} also has its faces isosceles. Indeed:

• Upper apical edge lengths:$$\backslash begin\{align\}$$

\overline{AU} &= \overline{AU'} = \sqrt{34} \,, \\[2pt]

\overline{AV} &= \overline{AV'} = 3\sqrt{10} \,;

\end{align}

• Base edge length (equal to previous example): $$$$

\overline{UV} = \overline{VU'} = \overline{U'V'} = \overline{V'U} = \sqrt{34} \,;

• Lower apical edge lengths (equal to upper edge lengths swapped):$$\backslash begin\{align\}$$

\overline{A'U} &= \overline{A'U'} = 3\sqrt{10} \,, \\[2pt]

\overline{A'V} &= \overline{A'V'} = \sqrt{34} \,.

\end{align}

In crystallography, regular right symmetric didigonal ({{math|8}}-faced) and ditrigonal ({{math|12}}-faced) scalenohedra exist.

The smallest geometric scalenohedra have eight faces, and are topologically identical to the regular octahedron. In this case ({{math|1=2n = 2×2}}), in crystallography, a regular right symmetric didigonal ({{math|8}}-faced) scalenohedron is called a tetragonal scalenohedron.

Let us temporarily focus on the regular right symmetric {{math|8}}-faced scalenohedra with {{math|1=h = r,}} i.e.

z_{A} = |z_{A'}| = x_{U} = |x_{U'}| = y_{V} = |y_{V'}|.

Their two apices can be represented as {{mvar|A, A'}} and their four basal vertices as {{mvar|U, U', V, V'}}:

$$\backslash begin\{alignat\}\{5\}$$

U &= (1,0,z), & \quad V &= (0,1,-z), & \quad A &= (0,0,1), \\

U' &= (-1,0,z), & \quad V' &= (0,-1,-z), & \quad A' &= (0,0,-1),

\end{alignat}

where {{mvar|z}} is a parameter between {{math|0}} and {{math|1}}.

At {{math|1=z = 0}}, it is a regular octahedron; at {{math|1=z = 1}}, it has four pairs of coplanar faces, and merging these into four congruent isosceles triangles makes it a disphenoid; for {{math|z > 1}}, it is concave.

If the {{math|2n}}-gon base is both isotoxal in-out and zigzag skew, then not all faces of the isotoxal right symmetric scalenohedron are congruent.

Example with five different edge lengths:

• The scalenohedron with isotoxal in-out zigzag skew {{math|2×2}}-gon base vertices {{mvar|U, U', V, V'}} and right symmetric apices {{mvar|A, A'}} $$\backslash begin\{alignat\}\{5\}$$

U &= (1,0,1), & \quad V &= (0,2,-1), & \quad A &= (0,0,3), \\

U' &= (-1,0,1), & \quad V' &= (0,-2,-1), & \quad A' &= (0,0,-3),

\end{alignat} has congruent scalene upper faces, and congruent scalene lower faces, but not all its faces are congruent. Indeed:

• Upper apical edge lengths:$$\backslash begin\{align\}$$

\overline{AU} &= \overline{AU'} = \sqrt{5} \,, \\[2pt]

\overline{AV} &= \overline{AV'} = 2\sqrt{5} \,;

\end{align}

• Base edge length:$$$$

\overline{UV} = \overline{VU'} = \overline{U'V'} = \overline{V'U} = 3;

• Lower apical edge lengths:$$\backslash begin\{align\}$$

\overline{A'U} &= \overline{A'U'} = \sqrt{17} \,, \\[2pt]

\overline{A'V} &= \overline{A'V'} = 2\sqrt{2} \,.

\end{align}

For some particular values of {{math|1=z{{sub|A}} = {{!}}z{{sub|A'}}{{!}}}}, half the faces of such a scalenohedron may be isosceles or equilateral.

Example with three different edge lengths:

• The scalenohedron with isotoxal in-out zigzag skew {{math|2×2}}-gon base vertices {{mvar|U, U', V, V'}} and right symmetric apices {{mvar|A, A'}} $$\backslash begin\{alignat\}\{5\}$$

U &= (3,0,2), & \quad V &= \left( 0,\sqrt{65},-2 \right), & \quad A &= (0,0,7), \\

U' &= (-3,0,2), & \quad V' &= \left( 0,-\sqrt{65},-2 \right), & \quad A' &= (0,0,-7),

\end{alignat} has congruent scalene upper faces, and congruent equilateral lower faces; thus not all its faces are congruent. Indeed:

• Upper apical edge lengths:$$\backslash begin\{align\}$$

\overline{AU} &= \overline{AU'} = \sqrt{34} \,, \\[2pt]

\overline{AV} &= \overline{AV'} = \sqrt{146} \,;

\end{align}

• Base edge length:$$$$

\overline{UV} = \overline{VU'} = \overline{U'V'} = \overline{V'U} = 3\sqrt{10} \,;

• Lower apical edge length(s): $$\backslash begin\{align\}$$

\overline{A'U} &= \overline{A'U'} = 3\sqrt{10} \,, \\[2pt]

\overline{A'V} &= \overline{A'V'} = 3\sqrt{10} \,.

\end{align}

A star bipyramid has a star polygon base, and is self-intersecting.{{cite journal |last= Rankin |first=John R. |year=1988 |title= Classes of polyhedra defined by jet graphics |journal=Computers & Graphics |volume=12 |issue=2 |pages=239–254 |doi=10.1016/0097-8493(88)90036-2}}

A regular right symmetric star bipyramid has congruent isosceles triangle faces, and is isohedral.

A {{math|p/q}}-bipyramid has Coxeter diagram {{CDD|node_f1|2x|node_f1|p|rat|q|node}}.

The dual of the rectification of each convex regular 4-polytopes is a cell-transitive 4-polytope with bipyramidal cells. In the following:

• {{mvar|A}} is the apex vertex of the bipyramid;
• {{mvar|E}} is an equator vertex;
• {{overline|{{mvar|EE}}}} is the distance between adjacent vertices on the equator (equal to 1);
• {{overline|{{mvar|AE}}}} is the apex-to-equator edge length;
• {{overline|{{mvar|AA}}}} is the distance between the apices.

The bipyramid 4-polytope will have {{mvar|V_A}} vertices where the apices of {{mvar|N_A}} bipyramids meet. It will have {{mvar|V_E}} vertices where the type {{mvar|E}} vertices of {{mvar|N_E}} bipyramids meet.

• {{tmath|N_\overline{AE} }} bipyramids meet along each type {{overline|{{mvar|AE}}}} edge.
• {{tmath|N_\overline{EE} }} bipyramids meet along each type {{overline|{{mvar|EE}}}} edge.
• {{tmath|C_\overline{AE} }} is the cosine of the dihedral angle along an {{overline|{{mvar|AE}}}} edge.
• {{tmath|C_\overline{EE} }} is the cosine of the dihedral angle along an {{overline|{{mvar|EE}}}} edge.

As cells must fit around an edge,

$$\backslash begin\{align\}$$

N_\overline{EE} \arccos C_\overline{EE} &\le 2\pi, \\[4pt]

N_\overline{AE} \arccos C_\overline{AE} &\le 2\pi.

\end{align}

File:Romb_deltoid.svg

A generalized {{mvar|n}}-dimensional "bipyramid" is any {{mvar|n}}-polytope constructed from an {{math|(n − 1)}}-polytope base lying in a hyperplane, with every base vertex connected by an edge to two apex vertices. If the {{math|(n − 1)}}-polytope is a regular polytope and the apices are equidistant from its center along the line perpendicular to the base hyperplane, it will have identical pyramidal facets.

A 2-dimensional analog of a right symmetric bipyramid is formed by joining two congruent isosceles triangles base-to-base to form a rhombus. More generally, a kite is a 2-dimensional analog of a (possibly asymmetric) right bipyramid, and any quadrilateral is a 2-dimensional analog of a general bipyramid.

• Trapezohedron

{{notelist|refs=

{{efn|name=right pyramids|1=The center of a regular polygon is unambiguous, but for irregular polygons sources disagree. Some sources only allow a right pyramid to have a regular polygon as a base. Others define a right pyramid as having its apices on a line perpendicular to the base and passing through its centroid. {{harvp|Polya|1954}} restricts right pyramids to those with a tangential polygon for a base, with the apices on a line perpendicular to the base and passing through the incenter.}}

}}

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• {{cite book | author= Anthony Pugh | year= 1976 | title= Polyhedra: A visual approach | publisher= University of California Press Berkeley | location= California | isbn= 0-520-03056-7 }} Chapter 4: Duals of the Archimedean polyhedra, prisms and antiprisms
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{{Commons category|Bipyramids}}

• {{mathworld |urlname=Dipyramid |title=Dipyramid}}
• {{mathworld | urlname = Isohedron | title = Isohedron}}
• [http://www.mathconsult.ch/showroom/unipoly/ The Uniform Polyhedra]
• [http://www.georgehart.com/virtual-polyhedra/vp.html Virtual Reality Polyhedra] The Encyclopedia of Polyhedra
• VRML models [http://www.georgehart.com/virtual-polyhedra/alphabetic-list.html (George Hart)] [http://www.georgehart.com/virtual-polyhedra/vrml/triangular_dipyramid.wrl <3>] [http://www.georgehart.com/virtual-polyhedra/vrml/octahedron.wrl <4>] [http://www.georgehart.com/virtual-polyhedra/vrml/pentagonal_dipyramid.wrl <5>] [http://www.georgehart.com/virtual-polyhedra/vrml/hexagonal_dipyramid.wrl <6>] [https://web.archive.org/web/20150203062131/http://www.georgehart.com/virtual-polyhedra/vrml/heptagonal_dipyramid.wrl <7>] [http://www.georgehart.com/virtual-polyhedra/vrml/octagonal_dipyramid.wrl <8>] [http://www.georgehart.com/virtual-polyhedra/vrml/enneagonal_dipyramid.wrl <9>] [http://www.georgehart.com/virtual-polyhedra/vrml/decagonal_dipyramid.wrl <10>]
• [http://www.georgehart.com/virtual-polyhedra/conway_notation.html Conway Notation for Polyhedra] Try: "dPn", where n = 3, 4, 5, 6, ... Example: "dP4" is an octahedron.

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Category:Polyhedra