Stellated octahedron
The stellated octahedron, also known as the stella octangula, is a non-convex polyhedral compound formed by the interpenetration of two dual regular tetrahedra, each with four equilateral triangular faces, resulting in a star-shaped figure with eight visible triangular faces, eight vertices, and twelve edges.[1][2] It represents the sole stellation of the regular octahedron, achieved by extending its eight triangular faces outward into pyramidal points until they meet to form the compound structure.[1][2] First illustrated in Luca Pacioli's 1509 treatise De Divina Proportione with woodcuts by Leonardo da Vinci, the figure was later named "stella octangula" by Johannes Kepler in his 1611 work Harmonices Mundi, where he explored its geometric harmony as a compound of tetrahedra.[1][2] Geometrically, its vertices coincide with those of a cube, and its edges align with the face diagonals of that cube, while the convex hull enclosing it is the cube itself.[1] For a stella octangula constructed from unit-edge tetrahedra, the surface area measures \frac{3}{2}\sqrt{3} and the volume is \frac{1}{8}\sqrt{2}.[1] This compound holds mathematical significance in polyhedral geometry, demonstrating how dual Platonic solids can intersect to form star polyhedra, and it has been inscribed within other polyhedra like the rhombic dodecahedron.[1] Beyond pure mathematics, it appears in artistic contexts, such as M.C. Escher's 1948 woodcut Stars, highlighting its aesthetic symmetry.[1]History and Definition
Discovery and Naming
The stellated octahedron first appeared in print through illustrations by Leonardo da Vinci in Luca Pacioli's 1509 treatise De divina proportione, where it was described as the "octaedron elevatum" or raised octahedron, presented as an augmentation of the Platonic solid octahedron using eight triangular pyramids.[3][1] This depiction highlighted its geometric harmony, aligning with the book's exploration of divine proportions and regular polyhedra, though Pacioli noted its 24 equilateral triangular faces and internal octahedral void perceptible only through imagination.[3] Over a century later, Johannes Kepler independently examined the figure and coined the name "stella octangula," translating to "eight-pointed star," in his 1619 publication Harmonices Mundi.[1][4] Kepler portrayed it as a harmonious union of two dual regular tetrahedra interpenetrating to form a star polyhedron, emphasizing its symmetry and aesthetic appeal within his broader cosmological framework of planetary harmonies and Platonic solids.[4] By the 19th century, systematic studies of polyhedral stellations led geometers to formally recognize the stella octangula as the sole stellation of the regular octahedron, distinguishing it from other star polyhedra through its regular compound structure.[5] This era solidified its dual identity: as a non-convex stellation extending the octahedron's faces and as the first regular polyhedral compound.[1] Terminology evolved accordingly, with "stellated octahedron" gaining prevalence in modern geometry to underscore the stellation process, while "stella octangula" preserved Kepler's classical Latin designation, and its compound nature—two tetrahedra sharing the same center—became a standard classification.[1][6]Geometric Definition
The stellated octahedron, also known as the stella octangula and named as such by Johannes Kepler, is a non-convex polyhedron featuring eight equilateral triangular faces that self-intersect to form a star-shaped figure.[1] This figure is classified as a regular polyhedral compound, specifically the compound of two dual regular tetrahedra, where one tetrahedron is rotated 180 degrees relative to the other.[1] It represents the sole stellation of the regular octahedron, obtained by extending the octahedron's faces until they meet to form the star configuration.[1] The component tetrahedra each possess the Schläfli symbol {3,3}, denoting a regular tetrahedron with triangular faces and three faces meeting at each vertex.[7] The compound exhibits a density of 2, reflecting the interpenetration of its two tetrahedral components, which overlap without filling space more densely.[7] Although isohedral—meaning all faces are equivalent under the symmetry group—the stellated octahedron is not a uniform star polyhedron like the Kepler–Poinsot solids, as it constitutes a compound rather than a single connected polyhedron with uniform vertex figures.[1]Geometric Properties
Faces, Edges, and Vertices
The stellated octahedron, also known as the stella octangula, is a polyhedral compound featuring 8 faces, each an equilateral triangle derived from the 4 faces of each constituent regular tetrahedron. These triangular faces intersect to form a star-shaped structure with 8 protruding points, characteristic of its stellated form.[1][8] It possesses 12 edges, all of equal length matching the side length of the component tetrahedra, with no shared edges between the two tetrahedra in the compound. The structure includes 8 vertices, which coincide with those of the two dual tetrahedra and are positioned at the vertices of an enclosing cube, exhibiting octahedral symmetry.[1][2][8] The Euler characteristic for this compound is calculated as V - E + F = 8 - 12 + 8 = 4, a value greater than 2 that underscores its non-simply connected topology as a compound rather than a genus-0 polyhedron surface.[1]Symmetry and Duality
The stellated octahedron, also known as the stella octangula, exhibits the full octahedral symmetry group O_h, which comprises 48 elements including 24 proper rotations and their reflections across mirror planes. This symmetry group acts transitively on the figure's vertices, edges, and faces, preserving the overall structure formed by the interpenetrating pair of regular tetrahedra. The group O_h is isomorphic to the symmetry group of the regular octahedron and cube, reflecting how the stellated octahedron can be viewed as a stellation of the octahedron.[9] The stellated octahedron is self-dual, meaning the compound is identical to its own dual polyhedron; specifically, each of the two tetrahedra serves as the dual of the other, with vertices of one corresponding to faces of the other under the duality operation. This self-duality arises from the geometric relationship where the second tetrahedron is obtained by taking the dual of the first and rotating it by 180 degrees. The property underscores the figure's balanced symmetry, where the polar reciprocity inherent in Platonic solids manifests in the compound form.[1] This dual structure is elegantly captured in the Coxeter diagram representation \{4,3\}[2\{3,3\}]\{3,4\}, which denotes the octahedral envelope enclosing the compound of two tetrahedral cores, illustrating the intertwined dual pairing of the tetrahedra within the overall symmetry framework.Construction Methods
As a Stellation of the Octahedron
The stellated octahedron, also known as the stella octangula, is formed through the stellation process applied to a regular octahedron, which involves extending the planes of its eight equilateral triangular faces outward until they intersect to create a new polyhedral surface.[1] This extension transforms the original convex octahedron into a non-convex star polyhedron by prolonging each face plane beyond its edges, where the intersections generate a self-intersecting envelope composed of 8 triangular faces from the original and additional pyramidal extensions.[2] Unlike more complex Platonic solids such as the icosahedron, which admit multiple stellations, the regular octahedron possesses only one complete stellation, resulting in the stella octangula.[1] This uniqueness arises from the symmetry and simplicity of the octahedron's facial arrangement, limiting the possible intersections to a single non-degenerate star form.[2] The resulting figure can also be interpreted as a faceting of the cube, where the six square faces of the cube are replaced by triangular pyramids that align with the cube's vertices, effectively creating the same star envelope through an inward faceting process reciprocal to the octahedron's outward stellation.[5] Visually, the stellated octahedron appears as a star with eight triangular pyramids protruding from the central octahedron's surface, each pyramid corresponding to an extended original face and contributing to the overall interpenetrating star shape.[2]As a Compound of Tetrahedra
The stellated octahedron, known as the stella octangula, is a regular polyhedron compound formed by two regular tetrahedra, where one tetrahedron serves as the dual of the other and is rotated by 180 degrees relative to it.[1] This dual pairing creates a symmetric structure that highlights the self-dual nature of the tetrahedron within the compound.[7] Johannes Kepler first recognized this figure as a distinct regular compound in his 1619 treatise Harmonices Mundi, distinguishing it from a single polyhedron and integrating it into his explorations of geometric harmony.[10][5] In the compound, the two tetrahedra interpenetrate deeply, with each edge of one tetrahedron crossing through the interior of the other, resulting in a star-like form bounded by eight triangular faces.[1][11] This interpenetration occurs without the edges of the tetrahedra intersecting one another directly; instead, they align to form the 12 face diagonals of an enclosing cube.[1] The compound possesses eight vertices in total, which are shared between the two tetrahedra, with each contributing its four distinct vertices to the overall set.[1][7] These vertices lie at positions such as the corners of a cube, ensuring the compound's regularity and uniformity.[12]Mathematical Aspects
Coordinates and Volume Formula
The vertices of the stellated octahedron (stella octangula) with edge length a are located at all eight combinations of coordinates \left( \pm \frac{\sqrt{2}}{4} a, \pm \frac{\sqrt{2}}{4} a, \pm \frac{\sqrt{2}}{4} a \right). These positions center the polyhedron at the origin and correspond to the vertices of an enclosing cube of side length \frac{\sqrt{2}}{2} a. One constituent tetrahedron comprises the four vertices with an even number of negative signs, while the other uses those with an odd number.[7] The volume V of the stellated octahedron is V = \frac{\sqrt{2}}{8} a^{3}. This result follows from viewing the figure as the union of two regular tetrahedra, each of volume \frac{\sqrt{2}}{12} a^{3}, whose intersection forms a regular octahedron of edge length \frac{a}{2} and volume \frac{\sqrt{2}}{24} a^{3}. The union volume is therefore V = 2 \cdot \frac{\sqrt{2}}{12} a^{3} - \frac{\sqrt{2}}{24} a^{3} = \frac{\sqrt{2}}{6} a^{3} - \frac{\sqrt{2}}{24} a^{3} = \frac{3 \sqrt{2}}{24} a^{3} = \frac{\sqrt{2}}{8} a^{3}. [13] Equivalently, the volume equals that of the central octahedron plus the volumes of eight smaller tetrahedra (triangular pyramids) attached to its faces. Each pyramid has base area \frac{\sqrt{3}}{4} \left( \frac{a}{2} \right)^{2} and appropriate height to reach the stellation vertices, yielding a combined pyramid volume of \frac{\sqrt{2}}{12} a^{3}. Adding this to the central octahedron's \frac{\sqrt{2}}{24} a^{3} confirms the total \frac{\sqrt{2}}{8} a^{3}. Direct integration over the star-shaped domain is possible but more complex.[2] The stellated octahedron's volume is three times that of its internal regular octahedron (the intersection of the two tetrahedra).Stella Octangula Numbers
The nth stella octangula number counts the number of unit tetrahedra required to form the nth stacked arrangement based on the stellated octahedron geometry, given by the formulaS_n = n(2n^2 - 1).
This sequence begins with S_0 = 0, S_1 = 1, S_2 = 14, S_3 = 51, and continues as listed in OEIS A007588.[14][15] These numbers relate to other figurate sequences by combining tetrahedral and octahedral numbers, specifically S_n = O_n + 8 T_{n-1}, where T_k = \frac{k(k+1)(k+2)}{6} is the kth tetrahedral number and O_k = \frac{k(2k^2 + 1)}{3} is the kth octahedral number.[15] For instance, S_2 = O_2 + 8 T_1 = 6 + 8 \cdot 1 = 14.[16] In discrete mathematics, stella octangula numbers arise in counting lattice points within polyhedral arrangements and serve as a model for figurate number generalizations to higher-dimensional polytopes.[17]