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Boy's surface

Boy's surface is an immersion of the real projective plane \mathbb{RP}^2 into three-dimensional Euclidean space \mathbb{R}^3, representing a non-orientable surface without pinch points or other singularities, though it features self-intersections along a single closed curve of double points that meets itself at one triple point.^[1]^[2] Discovered in 1901 by German mathematician Werner Boy as part of his doctoral dissertation under David Hilbert at the University of Göttingen, it provided the first explicit construction of such an immersion, countering the then-open question of whether \mathbb{RP}^2 could be smoothly embedded in \mathbb{R}^3 without self-intersections.^[3]^[1] Topologically, Boy's surface is equivalent to attaching a Möbius strip along the boundary of a disk, yielding a model of the projective plane with Euler characteristic 1.^[4] It can be parametrized using trigonometric functions over specific domains, such as u \in [-\pi/2, \pi/2] and v \in [0, \pi], resulting in an algebraic surface of degree 6 whose implicit equation was derived by Pascal Apéry in 1986.^[4] The surface's construction involves a polyhedral approximation with six squares and one triangle, where cone points are paired and smoothed to achieve the immersion.^[1] Boy's surface holds significance in differential geometry and topology, notably as a halfway model in demonstrations of sphere eversion, illustrating how to turn a 2-sphere inside out without tearing, following Stephen Smale's 1957 theorem.^[1] Its self-intersecting yet smooth nature has inspired physical models, including a bronze sculpture installed at the Mathematical Research Institute of Oberwolfach in 1991, and continues to serve as a canonical example of non-orientable immersions in mathematical visualization and education.^[4]

Introduction

Definition

Boy's surface is an immersion of the real projective plane \mathbb{RP}^2 into three-dimensional Euclidean space \mathbb{R}^3.^[5] As the image of this immersion, Boy's surface inherits the topological properties of \mathbb{RP}^2, which is a compact, non-orientable surface without boundary.^[6] The Euler characteristic of \mathbb{RP}^2 is \chi = 1, and its non-orientability arises from being topologically equivalent to a sphere with a single cross-cap.^[6] Boy's surface can be represented algebraically as a sextic surface, defined implicitly by a polynomial equation of degree 6 in three variables.^[7] This algebraic structure underscores its immersion in \mathbb{R}^3 while preserving the single-sided nature of the projective plane, where traversing the surface does not distinguish an inside from an outside.^[6]

History

Boy's surface was discovered in 1901 by Werner Boy, a German mathematician pursuing his doctoral thesis at the University of Göttingen under the supervision of David Hilbert. Hilbert had challenged Boy to demonstrate that the real projective plane could not be smoothly immersed in three-dimensional Euclidean space without singularities, a task rooted in early 20th-century investigations into the topology of non-orientable surfaces. To Hilbert's surprise, Boy succeeded in constructing such an immersion, describing it conceptually through algebraic curves and branch points in his thesis, which was defended on June 19, 1901, and later published in 1903.^[8]^[9]^[10] Despite this breakthrough, Boy's construction received limited attention in the mathematical community during the early decades of the 20th century, partly due to the lack of explicit parametrizations and visualizations that could make the abstract immersion more accessible. Boy himself provided only a qualitative description, and subsequent efforts to realize physical or graphical models were rudimentary, confining the surface to niche discussions in differential geometry and topology. It was not until the 1970s that interest revived, spurred by advances in computational geometry and the need for concrete representations of non-orientable manifolds. In 1978, French mathematician Bernard Morin provided the first explicit parametrization of Boy's surface, enabling clearer mathematical analysis and initial computer-generated visualizations.^[11]^[12] The 1980s marked a significant resurgence, with American mathematicians Robert Bryant and Rob Kusner developing an alternative parametrization in 1984 that emphasized minimal surface properties and three-fold rotational symmetry, facilitating further study of its geometric invariants. This work coincided with the construction of a prominent physical model at the Mathematical Research Institute of Oberwolfach, installed in 1991 as a gift from Mercedes-Benz, which served as a tangible emblem of the surface and drew wider attention to its topological significance. By the 1990s, popular science demonstrations helped disseminate awareness of Boy's surface through lectures and media on non-Euclidean geometries.^[13]^[8] Post-2000 developments have focused on computational advancements, enabling high-fidelity digital simulations and applications in visualization techniques. For instance, a 2009 method utilized Boy's immersion to color 3D line fields in diffusion tensor imaging data, providing smooth representations of orientation in complex datasets like brain scans. More recently, a 2022 analytical construction employed Thurston's corrugation technique with period-3 waves to generate Boy's surface programmatically, accompanied by a mechanical drawing machine for physical prototypes, highlighting ongoing intersections between topology and computational design. These efforts underscore the surface's enduring role in bridging theoretical mathematics with practical modeling up to 2025.^[14]^[15]

Parametrization

Original Construction

In 1901, Werner Boy developed the original construction of what is now known as Boy's surface as part of his dissertation under David Hilbert, demonstrating that the real projective plane \mathbb{RP}^2 admits an immersion into three-dimensional Euclidean space \mathbb{R}^3. Boy's method relied on a differential geometry approach, specifically solving a system of partial differential equations (PDEs) to find the immersion functions. This system was derived from conformal mapping principles, where \mathbb{RP}^2 is parametrized using isothermal coordinates that conformally map the surface to the sphere with antipodal identification, and incorporated branch curve analysis to handle the non-orientable topology and self-intersections. The historical equation setup involved the metric of \mathbb{RP}^2, which has constant Gaussian curvature K = 1, induced on \mathbb{R}^3. In isothermal coordinates (u,[v](/page/V.)) on \mathbb{RP}^2, the metric takes the form ds^2 = e^{2w(u,[v](/page/V.))} (du^2 + [dv](/page/DV)^2), and the immersion \mathbf{X}(u,[v](/page/V.)) = (x(u,[v](/page/V.)), y(u,[v](/page/V.)), [z](/page/Z)(u,[v](/page/V.))) must satisfy the condition that the first fundamental form matches this metric while ensuring compatibility with the flat ambient space. This leads to a system of nonlinear PDEs for the coordinate functions x, y, [z](/page/Z), stemming from the Gauss-Codazzi-Mainardi equations adapted for immersion: specifically, the structure equations require \mathbf{X}_u \cdot \mathbf{X}_u = \mathbf{X}_v \cdot \mathbf{X}_v = e^{2w} and \mathbf{X}_u \cdot \mathbf{X}_v = 0, along with the integrability condition for the second fundamental form to guarantee local embeddability without singularities beyond self-intersections. Boy approximated solutions numerically, often using polynomial expansions in spherical harmonics to iteratively satisfy these equations. The first explicit parametrization was provided by Bernard Morin in 1978.^[1] Despite its theoretical significance, Boy's original construction was implicit and non-explicit, providing no closed-form parametrization and necessitating numerical solving for any concrete realization or visualization of the surface. This limitation meant that early depictions relied on hand-drawn figures or approximate models, hindering immediate computational or physical implementations. Boy's immersion confirmed the existence of a non-trivial regular homotopy class for \mathbb{RP}^2 immersions in \mathbb{R}^3, distinct from the trivial class and representing one of two enantiomorphic classes (left- and right-handed versions).

Bryant–Kusner Parametrization

The Bryant–Kusner parametrization offers an explicit, conformal immersion of the real projective plane \mathbb{RP}^2 into \mathbb{R}^3, constructed as a minimizer of the Willmore functional among such immersions. This parametrization arises from solving a variational problem for conformal harmonic maps from the sphere to itself, with dihedral symmetry, yielding a "tight" immersion that achieves the global minimum Willmore energy of $12\pi while preserving three-fold rotational symmetry.^[16] The immersion is expressed using a complex parameter w in the closed unit disk |w| \leq 1, corresponding to the domain of \mathbb{RP}^2 via antipodal identification on the boundary circle |w| = 1.^[17] The coordinates are derived via stereographic projection and inversion of a companion minimal surface in \mathbb{R}^3, defined through Weierstrass-Enneper data optimized for the projective topology.^[18] Specifically, define

\begin{align*} g_1 &= -\frac{3}{2} \Im\left[ \frac{w (1 - w^4)}{w^6 + \sqrt{5}\, w^3 - 1} \right], \\ g_2 &= -\frac{3}{2} \Re\left[ \frac{w (1 + w^4)}{w^6 + \sqrt{5}\, w^3 - 1} \right], \\ g_3 &= \Im\left[ \frac{1 + w^6}{w^6 + \sqrt{5}\, w^3 - 1} \right] - \frac{1}{2}, \end{align*}

where \Re and \Im denote the real and imaginary parts, respectively. The position vector is then

(x,y,z) = \frac{(g_1, g_2, g_3)}{g_1^2 + g_2^2 + g_3^2}.

^[17]^[4] An equivalent trigonometric form, suitable for direct plotting, uses parameters \theta \in [-\pi/2, \pi/2] and \phi \in [0, \pi], with the immersion given by

\begin{align*} x &= \frac{\sqrt{2} \cos^2 \phi \cos 2\theta + \cos \theta \sin 2\phi}{2 - \sqrt{2} \sin 3\theta \sin 2\phi}, \\ y &= \frac{\sqrt{2} \cos^2 \phi \sin 2\theta - \sin \theta \sin 2\phi}{2 - \sqrt{2} \sin 3\theta \sin 2\phi}, \\ z &= \frac{3 \cos^2 \phi}{2 - \sqrt{2} \sin 3\theta \sin 2\phi}. \end{align*}

This form covers \mathbb{RP}^2 through appropriate identification of boundary curves, such as \theta \sim -\theta with sign flips in coordinates.^[4] The map is conformal at all but finitely many points, where singularities arise from the denominator vanishing, ensuring a smooth immersion except at self-intersection loci. The parametrization's basis in symmetric Weierstrass data, involving rational functions tuned via spherical harmonics approximations for the Gauss map, facilitates optimization for minimal self-intersections while maintaining the topology. Computationally, it excels in software implementations like Mathematica or MATLAB, as the rational expressions enable efficient evaluation and rendering without numerical instabilities over the compact domain; the resulting algebraic surface is sextic, though the parametrization is rational of degree 4 in the trigonometric variables.^[4]^[17]

Properties

Relation to the Real Projective Plane

The real projective plane, denoted \mathbb{RP}^2, is a fundamental non-orientable surface in topology, constructed as the quotient space of the 2-sphere S^2 under the antipodal identification, where each point x \in S^2 is identified with its opposite -x. This quotient captures the geometry of lines through the origin in \mathbb{R}^3, yielding a compact manifold that cannot be embedded in \mathbb{R}^3 without self-intersections but admits smooth immersions. \mathbb{RP}^2 is non-orientable, as evidenced by its representation via a disk with antipodal boundary points identified, which introduces a Möbius-like twist, and it has Euler characteristic \chi = 1, distinguishing it from orientable surfaces like the sphere (\chi = 2) or torus (\chi = 0). Boy's surface provides a explicit immersion of \mathbb{RP}^2 into \mathbb{R}^3, realizing the abstract topology of the projective plane in Euclidean 3-space. In this immersion, antipodal points on the underlying sphere are mapped to the same location on the surface, with the geometry's inherent twist embodying the non-trivial identifications of \mathbb{RP}^2. This construction, first described by Werner Boy in 1901, demonstrates how the projective plane's quotient structure manifests through a single connected component with threefold rotational symmetry, avoiding the need for cross-caps or handles in its visualization. Topologically, Boy's surface occupies one of the two distinct regular homotopy classes of immersions of \mathbb{RP}^2 into \mathbb{R}^3, the other being its mirror image; these classes are non-trivial, in contrast to the single homotopy class for immersions of the orientable sphere. The sphere S^2 acts as the universal cover of \mathbb{RP}^2, providing a double covering map that is two-to-one except at branch points corresponding to the quotient's fixed loci. In the context of Boy's surface, this covering is realized by an auxiliary immersed sphere that double covers the surface, illustrating how the projective identifications induce the immersion's global structure.

Self-Intersections and Singularities

Boy's surface is a smooth immersion of the real projective plane \mathbb{RP}^2 into \mathbb{R}^3, characterized by minimal self-intersections among generic immersions of this non-orientable surface. The self-intersection locus consists of a single continuous double curve, along which two sheets of the surface cross transversely, and this curve meets itself transversely at exactly one ordinary triple point, where three sheets intersect. There are no higher singularities, such as quadruple points or pinch points, distinguishing Boy's surface from immersions with cuspidal edges or non-transverse intersections. These features arise from the generic nature of the immersion, ensuring that all intersections are transverse and the differential of the parametrization is nowhere singular.^[2] Locally, near the triple point, the geometry resembles three transverse planes meeting at a common point, a standard model for an ordinary triple point in immersion theory. This configuration can be analyzed using jet spaces, where the 3-jet of the immersion at the preimage points satisfies the transversality conditions for a triple intersection without additional degeneracy. The double curve, away from the triple point, locally models two transverse sheets, akin to a Whitney umbrella but without the pinch singularity, as the immersion remains an immersion everywhere. Globally, the self-intersections stem from the non-orientability of \mathbb{RP}^2, which obstructs any embedding into \mathbb{R}^3—an orientable ambient space—necessitating an odd number of triple points congruent to 1 modulo 2, as dictated by the square of the first Stiefel-Whitney class.^[1] In comparison to the Roman surface, another early immersion of \mathbb{RP}^2 constructed by Steiner, Boy's surface exhibits fewer and simpler singularities: the Roman surface contains one quadruple point where four sheets meet and three double lines connecting it, resulting in more complex intersections. Boy's immersion achieves the minimal singularity count for generic maps, with just one triple point, making it optimal in this regard and highlighting its role as a canonical example of a non-orientable surface immersion. These self-intersections preclude an embedding but permit a smooth immersion, preserving the intrinsic geometry of \mathbb{RP}^2; notably, the Gaussian curvature remains well-defined on the parameter domain, though the image's metric degenerates at intersection loci without affecting the mean curvature's smoothness in the immersed metric.

Symmetries

Boy's surface possesses a symmetry group isomorphic to the cyclic group of order 3, generated by a rotation of 120° around an axis passing through its triple point and the geometric center of the surface. This rotational symmetry reflects the triangular structure inherent in the immersion of the real projective plane into Euclidean 3-space, distinguishing it from immersions with trivial or no non-trivial symmetries. The action of this symmetry group on the surface preserves the overall immersion class and the configuration of self-intersections, with the triple point fixed by the rotation. This invariance underscores the equitable distribution of singularities. While the abstract real projective plane admits larger symmetry groups, such as aspects of the icosahedral group in higher-dimensional contexts, the specific immersion realized by Boy's surface is constrained to this triangular rotational symmetry in \mathbb{R}^3.^[19] In the Bryant–Kusner parametrization, these symmetries manifest as conformal isometries, maintaining the angle-preserving properties of the map from the sphere to the immersed surface. Computationally, the rotation can be realized in \mathbb{R}^3 coordinates by a standard 120° rotation matrix about the symmetry axis, typically aligned with the z-axis in canonical positionings:

\begin{pmatrix} -\frac{1}{2} & -\frac{\sqrt{3}}{2} & 0 \\ \frac{\sqrt{3}}{2} & -\frac{1}{2} & 0 \\ 0 & 0 & 1 \end{pmatrix}

This matrix, applied to points on the surface, maps it to itself, confirming the order-3 cyclic action.

Applications and Models

Theoretical Applications

Boy's surface serves as a fundamental example in topology, illustrating the immersibility of the real projective plane \mathbb{RP}^2 into three-dimensional Euclidean space \mathbb{R}^3. This immersion, first constructed by Werner Boy, features a single triple point where a closed curve of double points meets itself, providing a concrete realization of a non-orientable closed surface without boundary in \mathbb{R}^3.^[20]^[2] In immersion theory, it exemplifies the challenges of embedding non-orientable manifolds, as \mathbb{RP}^2 cannot be embedded in \mathbb{R}^3 but admits such immersions, highlighting the distinction between embedding and immersion.^[21] The surface plays a key role in the study of regular homotopy classes of immersions. There are precisely two such classes for immersions of \mathbb{RP}^2 into \mathbb{R}^3, represented by Boy's surface and its mirror image, which are not regularly homotopic to each other.^[20] This aligns with the Smale-Hirsch theorem, which establishes a weak homotopy equivalence between the space of immersions and formal immersions, enabling the classification of immersions up to regular homotopy via stable normal bundle data.^[20] Additionally, Boy's surface is utilized in constructions involving immersed surfaces in higher dimensions; for instance, it can be regularly homotoped to a self-transverse immersion in \mathbb{R}^4 to adjust the Euler characteristic in analyses of double points and normal Euler numbers.^[22] In differential geometry, Boy's surface provides an important model for studying non-orientable immersions and their extrinsic properties. It demonstrates how self-intersections affect geometric invariants, serving as a benchmark for immersions with minimal singularity sets—a single triple point and a closed curve of double points.^[5] The surface is a critical point of the Willmore functional, which measures bending energy via the integral of the squared mean curvature, and it minimizes this energy among immersions of \mathbb{RP}^2 with threefold symmetry and a single triple point.^[5] This minimization property connects it to broader investigations of curvature flows and stable configurations, where the total Gaussian curvature, fixed at $2\pi by the Gauss-Bonnet theorem due to \chi(\mathbb{RP}^2) = 1, interacts with extrinsic distortions at self-intersection loci.^[5] As a sextic algebraic surface defined implicitly by a degree-six polynomial, Boy's surface finds applications in algebraic geometry, particularly in singularity theory. Its self-intersections correspond to singularities of the defining equation, allowing analysis of the topology and geometry through resolution of these singularities.^[23] This algebraic structure facilitates enumerative studies, such as counting nodes or cusps on real projective surfaces, and bridges differential topology with complex algebraic varieties via the complexification of the immersion.^[23] The Bryant–Kusner parametrization enables algorithmic generation of the surface for software-based explorations of non-orientable topology.^[14] Furthermore, its status as a Willmore minimizer in its homotopy class informs studies of minimal surfaces, where it appears in minimax problems for energy functionals and conformal deformations of higher-genus analogs.^[5]

Physical and Computational Models

Physical models of Boy's surface have been constructed to aid in the visualization and study of its non-orientable topology. The first notable physical realization was a large-scale sculpture installed at the Mathematical Research Institute of Oberwolfach on January 28, 1991, created as a gift from Mercedes-Benz and described in detail by Hermann Karcher; this steel model, approximately 1 meter in height, exemplifies the surface's triple-point self-intersection and threefold symmetry, serving as a landmark for geometric topology education.^[8]^[24] In more recent years, a delicate glass-blown model was crafted by scientific glassblower Lucas Clarke in collaboration with mathematician Clifford Stoll, completed around 2023 for educational demonstrations; this transparent sculpture highlights the surface's intricate tunnels and one-sided nature, allowing viewers to trace paths that demonstrate its projective plane properties without singularities beyond self-intersections.^[25]^[26] Construction methods for physical models often draw from the surface's topological definition as a disk attached to a Möbius strip along their boundaries. Paper crafting techniques involve cutting and folding a net composed of a central disk and an attached Möbius band, then gluing edges to form the immersed surface, which can be reinforced with tape for durability in classroom settings.^[4] For greater precision and scalability, 3D printing templates based on the Bryant–Kusner parametrization enable the production of solid or hollow models; for instance, students at the University of Illinois recreated historical plaster versions of Boy's surface using additive manufacturing in 2025, achieving watertight meshes suitable for handling and sectioning to reveal internal structure.^[27] Computational models facilitate interactive exploration and rendering of Boy's surface through software implementations of its parametrizations. In Mathematica, the Bryant–Kusner formulas can be visualized using ParametricPlot3D commands, allowing users to adjust parameters for smooth immersions and generate variations that minimize energy like Willmore energy.^[28] ^[29] Similarly, Blender supports scripting of the surface via Python or geometry nodes, as demonstrated in rendering pipelines that apply the parametrization to create high-fidelity meshes for animation and lighting studies.^[30] Animations in these tools often depict the homotopy from a disk-Möbius strip construction to the fully immersed Boy's surface, broadening the Möbius band's width while preserving topology, which helps illustrate the eversion process in sphere inversions.^[13] Modern advancements include 3D-scanned models for digital archives and educational kits, such as those used in topology courses to enable virtual dissection. Interactive visualizations integrate Boy's surface into virtual environments for studying non-orientable surfaces, enhancing accessibility for students through rotatable and sliceable models.^[31]

References

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Boy's Surface - American Mathematical Society
Boy's surface is an immersion of the real projec- tive plane in 3-dimensional space found by Werner. Boy in 1901 (he discovered it on assignment from.Missing: definition | Show results with:definition
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Boy's Surface - The Geometry Center
Jun 27, 1995 · Boy's surface is an image of a map from the real projective plane to R^3. It contains one continuous double point curve, which meets itself in a triple point.Missing: definition | Show results with:definition
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Boy Surface -- from Wolfram MathWorld
The Boy surface is a nonorientable surface that is one possible parametrization of the surface obtained by sewing a Möbius strip to the edge of a disk.Missing: definition | Show results with:definition
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[PDF] arXiv:math/9905020v2 [math.GT] 10 May 1999
The Boy's surface (left), an immersed projective plane with three-fold symmetry and a single triple point, minimizes Willmore's elastic bending energy. The ...
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Glossary: Real Projective Plane - The Geometry Center
The real projective plane is the unique non-orientable surface with Euler characteristic equal to 1. Classically, the real projective plane is defined as the ...
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The Boy Surface at Oberwolfach — MFO
The Boy surface is named after Werner Boy, who constructed this surface, which is an immersion of the real projective plane in Euclidean 3-space, ...Missing: original RP2<|control11|><|separator|>
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David Hilbert's doctoral students - University of St Andrews
We give the year of publication of the thesis, the students name, date of oral examination, and the title of the thesis. ... 1901 Werner Boy. 19 June 1901. Thesis ...Missing: dissertation | Show results with:dissertation
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Algebraic surface of degree 6. Boy's surface has 3 orifices leading to tunnels that come together in the central part.Missing: mathematics | Show results with:mathematics
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Jun 30, 2023 · In geometry, Boy's surface is an immersion of the real projective plane in 3-dimensional space found by Werner Boy in 1901.
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Boy discovered the surface when his thesis advisor David Hilbert asked him to prove it was impossible to immerse the real projective plane into three- ...
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Boy's Surface (Bryant-Kusner). This animation shows how Moebius strip can be transformed into Boy's Surface, by broadening Moebius strip's width.Missing: rediscovery 1970s
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[PDF] Wave, Boy's Surface, and Machine - The Bridges Archive
The Boy's surface in this paper consists of one half twist (𝑚 = 1) and period three waves (𝑛 = 3), thus among these immersions of R𝑃2, Boy's surface is the ...
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[PDF] Coloring 3D Line Fields Using Boy's Real Projective Plane Immersion
The first immersion of. RP2 in 3-space was discovered by the German mathematician Werner. Boy using hand-drawn figures in his 1901 thesis [4]; this immersion is.Missing: original | Show results with:original
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Über die Curvatura integra und die Topologie geschlossener Flächen
Download PDF · Mathematische Annalen Aims and scope Submit ... Cite this article. Boy, W. Über die Curvatura integra und die Topologie geschlossener Flächen.
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[PDF] Boy Surfaces, following Apery and Bryant-Kusner * See Möbius Strip ...
A Parametrization is obtained by first describing the minimal surface as an image of the Gaussian plane, then invert it in the unit sphere. Parameter lines.<|control11|><|separator|>
[21]
Symmetric Models of the Real Projective Plane - EMIS
Symmetric Models of the Real Projective Plane. H. R. Farran, Maria do Rosario ... Thus Boy's surface, in its `standard' form, is the most symmetrical ...
[22]
Dihedral Group D_3 -- from Wolfram MathWorld
The dihedral group D_3 is a particular instance of one of the two distinct abstract groups of group order 6. Unlike the cyclic group C_6 (which is Abelian), ...
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[PDF] Immersion theory for homotopy theorists
One may wonder whether this is an in- stance of Boy's surface or the mirror image of Boy's ... regular homotopy from the concatenation of ι(f) and g to g itself ...
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towards a classical knot theory for surfaces in r - Project Euclid
Jul 25, 1980 · regular homotopy ht from K1 to K2. The stages ... arbitrary genus). A well known immersion of RP2 in R3 is Boy's surface (for a photograph,.
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[PDF] On double points of immersed surfaces
Fix an immersion RP2 → R3. (e.g., Boy's surface), and by a regular homotopy move it to a self-transverse immersion α :RP2 → R4. If χ(F) is odd then let us ...
[26]
[PDF] 14 października 2019 r. Prof. François Apéry An algebraic ...
As a result, the Boy surface appears to be a real algebraic surface of degree six. However, the construction was a mix of geometry, differential topology ...
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NOTICES OF THE AMERICAN MATHEMATICAL SOCIETY
sculpture of Boy's surface, a gift to the insti- tute from Daimler-Benz. An article about the sculpture "Die Boysche Hache in Oberwolfach," by Hermann ...<|separator|>
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Oct 14, 2025 · Lucas Clarke is the Scientiﬁc Glass Blower at SFU, and. is perhaps the only person to have made a glass Boy Surface. We anticipate an ...
[29]
This Object Should've Been Impossible to Make - YouTube
Jun 21, 2023 · ... Cliff Stoll: https://amzn.to/449kJGJ Lucas Clarke's glassblowing ... glass-blown representation of the Boy's Surface mathematical concept.Missing: 1990s | Show results with:1990s
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3D Printable Boy Surface by Peter | Download free STL model
This is a watertight mesh of a Boy Surface. I created it in C++ using Visual Studio. Afterwards I used an online mesh repair service to make it printable.
[31]
Boy Surface and Variations - Wolfram Demonstrations Project
The Boy surface is a non-orientable surface, that is, you can move smoothly over the surface from one side to the other. Change the parameters.Missing: VR AR visualizations scans education 2020-2025
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May 1, 2015 · I'm trying to visualize Boy's surface using Bryant's parametrization, as per the MathWorld article. However, I'm not sure I understand the parametrization.Missing: φ | Show results with:φ
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Boy's surface is a one-sided surface in three-dimensional surface (or in mathematical jargon, an immersion of the real projective plane in R3)Missing: computational models Mathematica
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Topological Zoo. Mathematical visualization in virtual environment
Aug 9, 2025 · Differential geometry and topology are the areas of higher mathematics, which particularly require visual representation of studying objects ...