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Hendecagon

A hendecagon (also undecagon or 11-gon) is a with eleven sides and eleven vertices. The name derives from hendeka, meaning "eleven," and gonia, meaning "" or "corner." In , hendecagons are classified as either or irregular; a hendecagon has all sides of equal length and all interior measuring approximately 147.27 degrees, calculated as (180^\circ \times 11 - 360^\circ)/11. The sum of the interior angles for any hendecagon is 1620 degrees, and it contains 44 diagonals, derived from the general formulas $180^\circ(n-2) for angles and \frac{n(n-3)}{2} for diagonals where n=11. Unlike regular polygons with 3, 4, 5, 6, 8, 10, 12, 15, 16, 17, 20, 24, 32, 34, 48, 51, 64, 68, 80, 85, 96, 102, 128, 136, 160, 170, 192, 204, 240, 255, 256, 257, 272, 288, 320, 340, 384, 408, 480, 510, 512, 514, 544, 576, 640, 680, or 768 sides, a hendecagon cannot be constructed using only a and under classical rules, as 11 is a not of the form $2^k p_1 p_2 \dots p_m where the p_i are distinct Fermat primes. Notable applications include the 11-sided shape of the Canadian one-dollar "" coin (introduced 1987), which has a plain edge and provides a distinctive non-circular form for vending machine recognition. The U.S. coin (1979–1981, 1999) is circular with a reeded edge and an 11-sided inner border on both sides for tactile distinction from the quarter.

Definition and Terminology

Definition

A hendecagon is a polygon with exactly 11 sides and 11 vertices. It is also known as an undecagon in some mathematical contexts. In modern terminology, it is equivalently referred to as an 11-gon. Hendecagons can be classified based on their shape and boundary structure. They may be convex, where all interior angles are less than 180° and no sides bend inwards, or concave, featuring at least one interior angle greater than 180°. Additionally, hendecagons are either simple, with non-intersecting sides that do not cross themselves, or self-intersecting, where the boundary intersects at points other than vertices. The standard form considered in most geometric discussions is the simple convex hendecagon. As a polygon with 11 sides, a hendecagon has a sum of interior equal to (11-2) \times 180^\circ = 1620^\circ. In the case, each interior is less than 180° but does not equal it, ensuring the polygon's convexity.

The term "hendecagon" originates from the words ἕνδεκα (héndeka), meaning "eleven," and γωνία (gonía), meaning "" or "corner," referring to a figure with eleven . This etymology reflects the tradition of naming polygons based on their number of sides and , with the word entering English as a borrowing from "hendécagone," which derives from Latin "hendecagonus" via the same roots. The records the earliest known English usage in 1648, in a work by Gerbier, though more prominent appearances in mathematical literature occurred in 1704 within John Harris's Lexicon Technicum, or an Universal English Dictionary of and Sciences, where "hendecagon" and the variant "endecagon" described an eleven-sided . An alternative term, "undecagon," stems from the Latin "undecim" (eleven, combining "unus" for one and "decem" for ten) paired with the "-gon" suffix, creating a Latin- form that some sources consider less consistent with the predominantly for polygons. This term first appeared in English in in Chambers's Cyclopædia, and while used interchangeably with "hendecagon" in early modern texts, it has become less common in contemporary . Mathematical authorities, such as , prefer "hendecagon" for its purity of derivation, avoiding the linguistic mixing in "undecagon." In historical context, the terminology emerged in the early amid growing interest in polygonal figures in European mathematics, building on ancient Greek studies of polygons by in his , where regular polygons were inscribed in circles but eleven-sided figures received no special emphasis due to their non-constructibility with and . Prior to standardized terms, English mathematical often referred descriptively to an "eleven-sided figure" or "polygon with eleven sides," as seen in 17th-century works. Over time, particularly from the onward, "hendecagon" became the conventional term in textbooks and scholarly publications, reflecting a broader standardization of polygon influenced by classical languages.

Geometric Properties

General Properties

A hendecagon is a with eleven sides and eleven vertices, and its general properties apply to both and forms, though is often assumed for simplicity in basic analyses. Unlike hendecagons, irregular variants may have unequal side lengths and , leading to varied geometric behaviors while adhering to fundamental axioms. These properties provide the foundational metrics for understanding any hendecagon's structure and enclosure capabilities. The perimeter P of a hendecagon is the total length of its boundary, calculated as the sum of its eleven side lengths: P = s_1 + s_2 + \dots + s_{11}, where the s_i may differ in irregular cases. This measure is essential for assessing the polygon's outline and comparing it to other shapes with fixed boundaries. For hendecagons that are tangential (admitting an incircle tangent to all sides), the is the from the to any side, enabling area computation via A = \frac{1}{2} P r, where r is the inradius equal to the apothem. Similarly, circumscribed hendecagons (those inscribed in a ) possess a circumradius R, the from the circumcenter to each , which bounds the polygon's extent within a circular . These radii concepts extend to irregular forms only when the respective tangential or cyclic conditions hold. The sum of the exterior angles of any hendecagon is always $360^\circ, with each exterior angle formed by extending one side and measuring the turn at a ; in irregular cases, these angles are unevenly distributed but collectively complete a full . This holds regardless of side or interior angle variations, distinguishing polygons from non-convex ones where intersections may alter turning paths. Convexity in a hendecagon requires all interior angles to be less than $180^\circ and no sides to intersect except at vertices, ensuring the polygon lies entirely on one side of each line and maintains a simply connected interior without self-overlaps. This criterion prevents re-entrant features common in polygons and guarantees properties like the exterior angle sum. Among all figures with a given perimeter P, the states that the enclosed area A satisfies $4\pi A \leq P^2, with equality approached by a ; for hendecagons, this implies a maximum area bounded away from the circle's optimum, achieved closest by near-circular irregular forms but strictly less due to polygonal constraints. This inequality quantifies efficiency in area enclosure for any hendecagon, highlighting the trade-off between straight edges and curved ideals.

Regular Hendecagon Properties

A regular hendecagon is an equilateral and equiangular eleven-sided polygon inscribed in a circle, with its vertices corresponding to the non-real 11th roots of unity in the complex plane. These roots satisfy the 11th cyclotomic polynomial \Phi_{11}(x) = x^{10} + x^9 + \cdots + x + 1 = 0, which is irreducible over the rationals and defines the minimal extension field for the coordinates of the vertices when placed on the unit circle. The interior angle of a regular hendecagon measures exactly \frac{(11-2) \times 180^\circ}{11} = \frac{1620^\circ}{11} \approx 147.2727^\circ. The central angle subtended by each side at the center of the circumscribed circle is \frac{360^\circ}{11} \approx 32.7273^\circ. The perimeter is simply 11 times the side length s, so P = 11s. The area A of a regular hendecagon can be expressed in terms of the side length s as A = \frac{11}{2} s^2 \cot\left(\frac{\pi}{11}\right), or equivalently \frac{11 s^2}{4 \tan(\pi/11)}; alternatively, in terms of the circumradius r, it is A = \frac{11}{2} r^2 \sin\left(\frac{2\pi}{11}\right). A regular hendecagon has four distinct classes of diagonals, corresponding to the chords spanning 2, 3, 4, or 5 vertices. The length of the diagonal spanning k vertices (for k = 2, 3, 4, 5) with side length s is given by d_k = s \cdot \frac{\sin(k \pi / 11)}{\sin(\pi / 11)}, or in terms of the circumradius r, d_k = 2 r \sin(k \pi / 11). These lengths exhibit ratios that can be expressed using trigonometric identities derived from the angles \pi/11, $2\pi/11, etc., analogous to the golden ratio in pentagons but involving solutions to the 11th cyclotomic field.

Construction Methods

Theoretical Limitations

The Gauss–Wantzel theorem establishes that a regular n-gon can be constructed with compass and straightedge if and only if n = 2^k \prod p_i, where k \geq 0 and the p_i are distinct Fermat primes. Fermat primes are primes of the form $2^{2^m} + 1, with the only known such primes being 3, 5, 17, 257, and 65537. Since 11 is a prime number but not a Fermat prime, a regular hendecagon cannot be constructed using these classical tools. In 1837, Pierre Wantzel provided the rigorous proof of the necessity condition in this theorem, demonstrating that for odd primes p like 11 that are not Fermat primes, the required over has greater than a power of 2, rendering the impossible. Wantzel's work showed that such constructions demand solving irreducible polynomials of prime greater than 2, which cannot be achieved through extensions alone. The underlying algebraic obstruction arises from the \mathbb{Q}(\zeta_{11}), where \zeta_{11} = e^{2\pi i / 11} is a primitive 11th root of unity; the minimal of \cos(2\pi/11) over the rationals has degree 5, as it generates the real subfield of degree \phi(11)/2 = 5. This degree-5 extension is not a tower of extensions and thus not solvable by radicals of degree 2, confirming the non-constructibility. As a result, the exact coordinates of a hendecagon's vertices lie outside any extension of the rationals, necessitating advanced techniques such as methods or higher-degree approximations for precise representations beyond classical geometry.

Practical Constructions

Although a regular hendecagon cannot be constructed exactly using only a compass and unmarked straightedge, approximations can achieve high accuracy with classical tools. One historical method, described by Albrecht Dürer in his 1525 treatise Underweysung der Messung mit dem Zirckel und Richtscheyt, involves drawing a circle of radius R centered at the origin and a second circle of radius $9R/16 centered at (R, 0); the line from the origin to one of their intersection points forms an angle of approximately $32.6696^\circ with the x-axis, close to the ideal central angle of $360^\circ / 11 \approx 32.7273^\circ, yielding a relative error under 0.2%. This approach, involving intersecting circles and angle bisections, produces an 11-sided figure suitable for artistic or practical drawing with minimal deviation. Modern refinements extend these classical techniques for better precision. Using a marked ruler (also known as a ), the regular hendecagon can be constructed exactly by solving field extensions related to the 11th roots of unity through verging operations, as demonstrated in a 2014 proof that leverages to confirm constructibility within this augmented toolkit. Similarly, two-fold origami on a square sheet enables an exact construction by performing simultaneous folds that achieve the necessary angle divisions, overcoming the limitations of single-fold ; the method involves a sequence of creases to align vertices at equal arcs, detailed in a 2018 geometric analysis. For exact computation, the vertices of a regular hendecagon inscribed in a are given by the coordinates \left( \cos \frac{2\pi k}{11}, \sin \frac{2\pi k}{11} \right) for k = 0 to $10, derived from the roots of the 11th \Phi_{11}(x) = x^{10} + x^9 + \cdots + x + 1 = 0. These algebraic values, involving nested radicals, can be calculated precisely using computer algebra systems such as or , allowing for numerical plotting or digital rendering without approximation errors. Geometric tools simplify practical drawing. With a protractor and , divide a into 11 equal arcs by marking successive of approximately $32.727^\circ from a starting point on the , connecting the points to form the ; this method is straightforward for educational or manual sketching. In CAD software like , the command creates a regular 11-sided figure by specifying the number of sides, center point, and (for circumscribed) or side length (for inscribed), automating precise placement via algorithms. Visualization aids further support construction and analysis. The parametric equations x(\theta) = r \cos \theta, y(\theta) = r \sin \theta with \theta = \frac{2\pi k}{11} for k = 0 to $10 enable plotting in graphing software, while the side length approximates s \approx 2 r \sin(\pi / 11) for radius r, providing a quick metric for scaling physical models.

Symmetry and Group Theory

Dihedral Symmetry

The symmetry group of the regular hendecagon is the dihedral group D_{11}, which consists of all isometries that map the to itself and has order 22. This group is generated by a r of 11, corresponding to a counterclockwise turn by \frac{360^\circ}{11}, and a s of 2 across an through a and the of the opposite side, satisfying the \langle r, s \mid r^{11} = s^2 = 1, \, s r s^{-1} = r^{-1} \rangle. Since the number of sides 11 is odd, D_{11} is non-abelian, as reflections do not commute with non-trivial rotations. The subgroup of rotational symmetries is cyclic of order 11; as 11 is prime, it has exactly two subgroups, the trivial subgroup and itself, both cyclic of order dividing 11. Additionally, D_{11} contains 11 distinct subgroups of order 2, each generated by one of the reflections. A fundamental domain for the action of D_{11} on the is a single sector spanning \frac{180^\circ}{11} \approx 16.36^\circ.

Rotational and Reflection Symmetries

The regular hendecagon possesses 11 rotational symmetries, corresponding to rotations about its center by angles of k \times \frac{360^\circ}{11} for integers k = 0, 1, \dots, 10, which map the figure onto itself. These rotations form the cyclic of order 11 within the , preserving the orientation of the . In addition to rotations, the regular hendecagon has 11 reflection symmetries, each across a line passing through the center. Due to the odd number of sides (n = 11), all of these mirror lines pass through a vertex and the midpoint of the opposite side. This configuration arises because, for regular polygons with an odd number of sides, no two vertices are directly opposite each other, unlike in even-sided polygons such as the dodecagon, where some reflection axes connect pairs of opposite vertices. Compositions of these symmetries demonstrate their interplay; for instance, applying a followed by a by \frac{360^\circ}{11} yields another , as rotations conjugate one to another within the structure. Geometrically, the 11 reflection axes, all intersecting at , divide the surrounding into 22 congruent angular sectors, each spanning \frac{180^\circ}{11} \approx 16.36^\circ. When extended to the boundary of the hendecagon by connecting to all vertices and side midpoints along these axes, the itself is subdivided into congruent isosceles triangles, highlighting the dense packing.

Applications

Numismatic Uses

The use of hendecagonal shapes in coin design emerged primarily for practical purposes such as distinguishing denominations from similar-sized round and enhancing security against counterfeiting. The eleven-sided provides a tactile profile and rolling dynamics that aid identification, particularly for the visually impaired, while complicating unauthorized replication due to the irregular compared to more common five- or seven-sided . One prominent example is Canada's one-dollar coin, known as the , introduced in 1987 to replace the one-dollar bill. This regular hendecagon measures 26.5 mm across the flats. From 1987 to 2011, it weighed 7 g with a core plated in aureate ; since 2012, it weighs 6.27 g with a brass-plated steel core and added security features including laser-etched maple leaves. Its eleven sides were specifically chosen to differentiate it from the 25-cent quarter, which has a similar size and golden color, thereby reducing errors and improving circulation efficiency. The design has remained in , with over 4 billion pieces minted as of 2023, and its shape has become iconic in Canadian . In , the two-rupee coin adopted a hendecagonal form in 1992 as part of the National Integration series, used until 2004. With a of 26 mm, weight of 6 g, and copper-nickel composition, the coin's eleven sides helped distinguish it from the slightly smaller one-rupee piece, promoting ease of use in transactions and deterring counterfeits through its non-circular profile. Various thematic obverse designs, such as "," were issued on this shape until it reverted to circular in 2005, reflecting cultural motifs while maintaining the security features. The Dominican Republic's one-peso coin, issued since 1993, also employs an eleven-sided shape for similar anti-counterfeiting benefits. Measuring 25 mm in diameter and weighing 6.4-6.5 g in brass-plated , it features portraits of independence figures like on the obverse and the on the reverse. This design enhances recognizability in everyday commerce and aligns with global trends toward non-round coins for security. The adoption of hendecagons in these currencies reflects a broader evolution in numismatic design since the , when polygonal shapes gained popularity to address issues like coin mix-ups in automated systems. This trend was pioneered by coins such as the United Kingdom's seven-sided 50 pence (1969) and 20 pence (1982), which inspired international mints to experiment with odd-sided polygons for improved functionality and fraud resistance.

Architectural and Design Applications

Due to the mathematical complexity of constructing a regular hendecagon, as it is not possible with and alone, its use in architecture remains rare and often involves approximations. One notable ancient example is the clypeus, a monumental shield decoration in the enclosure at (modern , ), dating to the period. Here, the perimeter ring approximates a regular hendecagon with exterior angles of approximately 32.72°, achieved by subdividing the diameter into 28 parts and combining it with an and Archimedes' approximation of π (); this design integrates meanders and symbolic elements like a Jupiter pearl ring, demonstrating advanced geometric precision for decorative purposes. In , tools have enabled more precise incorporation of hendecagonal forms, particularly in installations emphasizing radial and environmental performance. A prominent example is the Shirdi Sai Baba Temple in Koppur, , designed by rat[LAB] Studio, with construction ongoing or recently completed in the . The structure evolves the hendecagon into a three-dimensional , forming the basis for algorithmic iterations that balance with structural stability, including an 11-point circular flooring pattern for a rhythmic spiritual promenade; this 11.11-acre complex draws on Vaastu principles while using computational modeling to assess daylight, , and load distribution. Beyond buildings, hendecagons appear in jewelry design for their unique faceting and symbolic representation of the number 11, often denoting completeness or rarity. For instance, custom eternity rings by designer Candice Pool Neistat feature hendecagonal bands set with baguette diamonds, totaling up to 1.95 carats, which highlight the polygon's geometric sophistication in wearable art. Antique pieces, such as early 20th-century 9ct gold bangles shaped as hendecagons with engraved sides, further illustrate this application, adding textural interest through the 11 facets. Fabrication challenges persist due to the hendecagon's irregular angles and non-constructibility, historically leading to approximations in traditional methods like or . However, advancements in since the have facilitated accurate realizations of hendecagonal forms in and , allowing for complex parametric facades and custom jewelry without manual precision limitations; this technology supports layer-by-layer deposition of materials like polymers or metals, enabling scalable production of 11-sided motifs while minimizing errors in .

Related Polygons

Stellate Hendecagons

Stellate hendecagons, also known as hendecagrams, are self-intersecting star polygons derived from the 11 vertices of a hendecagon by connecting every k-th , where k=2, 3, 4, or 5. These are denoted by the Schläfli symbols {11/2}, {11/3}, {11/4}, and {11/5}, respectively, with densities ranging from 2 to 5, indicating the number of times the boundary winds around the center before closing. The {11/2} stellate hendecagon is formed by connecting every second among the 11 equally spaced points on a circle, resulting in a single since 11 and 2 are coprime. Unlike compounds that decompose into multiple separate polygons, this figure maintains a unified structure with intersecting edges creating a star-like appearance. Each {11/k} has an isogonal conjugate and retrograde form given by {11/(11-k)}, which are enantiomorphs—non-superimposable mirror images of each other—differing only in the direction of traversal around the vertices. For example, {11/2} and {11/9} (equivalent to {11/2} in reverse), or {11/3} and {11/8}, represent such chiral pairs, preserving the same density but exhibiting opposite handedness. Constructing a stellate hendecagon shares the same theoretical limitations as the regular hendecagon, as the vertices coincide with those of the {11} form, which cannot be achieved using only and due to the 11 not being a Fermat prime. Instead, practical realizations rely on generalized trigonometric solutions, such as computing vertex coordinates via of \frac{2\pi}{11} radians and connecting the appropriate points numerically or with auxiliary tools. Stellate hendecagons exhibit aesthetic properties that lend them to ornamental art and designs inspired by tessellations, similar to those explored by , where intersecting patterns create intricate, non-convex motifs. Their complex windings and symmetries have been incorporated into geometric decorations, evoking depth and infinity through layered intersections.

Hendecagonal Polyhedra

A hendecagonal is a composed of two parallel hendecagonal bases connected by eleven rectangular lateral faces. This structure results in a total of thirteen faces, thirty-three edges, and twenty-two , maintaining the dihedral symmetry of the base polygons. Similarly, the hendecagonal is a featuring two parallel hendecagonal bases offset by half a side length relative to each other, linked by twenty-two equilateral triangular lateral faces. It possesses twenty-four faces, forty-four edges, and twenty-two , with each vertex incident to one hendecagon and two triangles. The hendecagonal pyramid is a polyhedron with a single regular hendecagonal base and eleven isosceles triangular lateral faces converging at an apex. This configuration yields twelve faces, twenty-two edges, and twelve vertices, where the apex connects directly to each base vertex. For such a pyramid with base side length a and height h, the volume V is calculated as V = \frac{1}{3} A h, where A is the area of the regular hendecagonal base, given by A = \frac{11 a^2}{4} \cot\left(\frac{\pi}{11}\right). Non-regular polyhedra incorporating hendecagonal faces include extensions of cupola structures, such as the hendecagonal cupola, which combines a hendecagon and a regular icosidigon (22-gon) as bases with eleven equilateral triangles and eleven squares in an alternating band. Due to the non-constructibility of the hendecagon using compass and straightedge—stemming from 11 being a prime that is not a Fermat prime (i.e., not of the form $2^k \prod p_i where the p_i are distinct Fermat primes)—such polyhedra with hendecagonal faces cannot be exactly constructed geometrically and are typically idealized in theoretical models or approximated numerically.

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