Comparison triangle

Last updated December 12, 2024

In metric geometry, comparison triangles are constructions used to define higher bounds on curvature in the framework of locally geodesic metric spaces, thereby playing a similar role to that of higher bounds on sectional curvature in Riemannian geometry.

Definitions

Comparison triangles

Let ${\textstyle M_{0}^{2}=\mathbb {E} ^{2}}$ be the euclidean plane, ${\textstyle M_{1}^{2}=\mathbb {S} ^{2}}$ be the unit 2-sphere, and ${\textstyle M_{-1}^{2}=\mathbb {H} ^{2}}$ be the hyperbolic plane. For ${\textstyle k>0}$ , let ${\textstyle M_{k}^{2}}$ and ${\textstyle M_{-k}^{2}}$ denote the spaces obtained, respectively, from ${\textstyle M_{1}^{2}}$ and ${\textstyle M_{-1}^{2}}$ by multiplying the distance by ${\textstyle {\frac {1}{\sqrt {|k|}}}}$ . For any ${\textstyle k\in \mathbb {R} }$ , ${\textstyle M_{k}^{2}}$ is the unique complete, simply-connected, 2-dimensional Riemannian manifold of constant sectional curvature ${\textstyle k}$ .

Let $X$ be a metric space. Let $T$ be a geodesic triangle in $X$ , i.e. three points $p$ , $q$ and $r$ and three geodesic segments ${\textstyle [p,q]}$ , ${\textstyle [q,r]}$ and ${\textstyle [r,p]}$ . A comparison triangle $T*$ in ${\textstyle M_{k}^{2}}$ for $T$ is a geodesic triangle in ${\textstyle M_{k}^{2}}$ with vertices $p'$ , $q'$ and $r'$ such that ${\textstyle d(p,q)=d(p',q')}$ , ${\textstyle d(p,r)=d(p',r')}$ and ${\textstyle d(r,q)=d(r',q')}$ .

Such a triangle, when it exists, is unique up to isometry. The existence is always true for ${\textstyle k\leq 0}$ . For ${\textstyle k>0}$ , it can be ensured by the additional condition ${\textstyle d(p,q)+d(q,r)+d(r,p)\leq {\frac {2\pi }{\sqrt {k}}}}$ (i.e. the length of the triangle does not exceed that of a great circle of the sphere ${\textstyle M_{k}^{2}}$ ).

Comparison angles

The interior angle of ${\textstyle T*}$ at ${\textstyle p'}$ is called the comparison angle between ${\textstyle q}$ and ${\textstyle r}$ at ${\textstyle p}$ . This is well-defined provided ${\textstyle q}$ and ${\textstyle r}$ are both distinct from ${\textstyle p}$ , and only depends on the lengths ${\textstyle d(p,q),d(q,r),d(p,r)}$ . Let it be denoted by ${\textstyle {\overline {\angle }}_{p,q,r}^{(k)}}$ . Using inverse trigonometry, one has the formulas: $\cos({\overline {\angle }}_{p,q,r}^{(0)})={\frac {d(q,r)^{2}-d(p,q)^{2}-d(p,r)^{2}}{2d(p,q)d(p,r)}},$ $\cos({\overline {\angle }}_{p,q,r}^{(k)})={\frac {\cos({\sqrt {k}}d(q,r))-\cos({\sqrt {k}}d(p,q))\cos({\sqrt {k}}d(p,r))}{\sin({\sqrt {k}}d(p,q))\sin({\sqrt {k}}d(p,r))}}~~{\text{for}}~~k>0,$ $\cos({\overline {\angle }}_{p,q,r}^{(k)})={\frac {\cosh({\sqrt {-k}}d(p,q))\cosh({\sqrt {-k}}d(p,r))-\cosh({\sqrt {-k}}d(q,r))}{\sinh({\sqrt {-k}}d(p,q))\sinh({\sqrt {-k}}d(p,r))}}~~{\text{for}}~~{k<0}.$

Alexandrov angles

Comparison angles provide notions of angles between geodesics that make sense in arbitrary metric spaces. The Alexandrov angle, or inner angle, between two nontrivial geodesics ${\textstyle c,c'}$ with ${\textstyle c(0)=c'(0)}$ is defined as $\angle _{c,c'}=\liminf _{t,t'\rightarrow 0}{\overline {\angle }}_{c(0),c(t),c(t')}.$

Comparison tripods

The following similar construction, which appears in certain possible definitions of Gromov-hyperbolicity, may be regarded as a limit case when ${\textstyle k\rightarrow -\infty }$ .

For three points ${\textstyle x,y,z}$ in a metric space ${\textstyle X}$ , the Gromov product of ${\textstyle x}$ and ${\textstyle y}$ at ${\textstyle z}$ is half of the triangle inequality defect: $(x,y)_{z}={\frac {1}{2}}(d(x,z)+d(y,z)-d(x,y))$ Given a geodesic triangle ${\textstyle \Delta }$ in ${\textstyle X}$ with vertices ${\textstyle (p,q,r)}$ , the comparison tripod ${\textstyle T_{\Delta }}$ for ${\textstyle \Delta }$ is the metric graph obtained by gluing three segments ${\textstyle [p',c_{p}],[q',c_{q}],[r',c_{r}]}$ of respective lengths ${\textstyle (q,r)_{p},(r,p)_{q},(p,q)_{r}}$ along a vertex ${\textstyle c}$ , setting ${\textstyle c_{p}=c_{q}=c_{r}=c}$ .

One has ${\textstyle d(p',q')=d(p,q),~~d(q',r')=d(q,r),~~d(r',p')=d(r,p),}$ and ${\textstyle T_{\Delta }}$ is the union of the three unique geodesic segments ${\textstyle [p',q'],[q',r'],[r',p']}$ . Furthermore, there is a well-defined comparison map ${\textstyle f_{\Delta }:\Delta \longrightarrow T_{\Delta }}$ with ${\textstyle f_{\Delta }(p)=p',f_{\Delta }(q)=q',f_{\Delta }(r)=r',}$ such that ${\textstyle f_{\Delta }}$ is isometric on each side of ${\textstyle \Delta }$ . The vertex ${\textstyle c}$ is called the center of ${\textstyle T_{\Delta }}$ , and its preimage under ${\textstyle f_{\Delta }}$ is called the center of ${\textstyle \Delta }$ , its points the internal points of ${\textstyle \Delta }$ , and its diameter the insize of ${\textstyle \Delta }$ .

One way to formulate Gromov-hyperbolicity is to require ${\textstyle f_{\Delta }}$ not to change the distances by more than a constant ${\textstyle \delta \geq 0}$ . Another way is to require the insizes of triangles ${\textstyle \Delta }$ to be bounded above by a uniform constant ${\textstyle \delta '\geq 0}$ .

Equivalently, a tripod is a comparison triangle in a universal real tree of valence ${\textstyle \geq 3}$ . Such trees appear as ultralimits of the ${\textstyle M_{k}^{2}}$ as ${\textstyle k\rightarrow -\infty }$ .^[1]

The CAT(k) condition

The Alexandrov lemma

In various situations, the Alexandrov lemma (also called the triangle gluing lemma) allows one to decompose a geodesic triangle into smaller triangles for which proving the CAT(k) condition is easier, and then deduce the CAT(k) condition for the bigger triangle. This is done by gluing together comparison triangles for the smaller triangles and then "unfolding" the figure into a comparison triangle for the bigger triangle.

Related Research Articles

In mathematics, a hyperbola is a type of smooth curve lying in a plane, defined by its geometric properties or by equations for which it is the solution set. A hyperbola has two pieces, called connected components or branches, that are mirror images of each other and resemble two infinite bows. The hyperbola is one of the three kinds of conic section, formed by the intersection of a plane and a double cone. If the plane intersects both halves of the double cone but does not pass through the apex of the cones, then the conic is a hyperbola.

In geometry, a tetrahedron, also known as a triangular pyramid, is a polyhedron composed of four triangular faces, six straight edges, and four vertices. The tetrahedron is the simplest of all the ordinary convex polyhedra.

<span class="mw-page-title-main">Ellipsoid</span> Quadric surface that looks like a deformed sphere

An ellipsoid is a surface that can be obtained from a sphere by deforming it by means of directional scalings, or more generally, of an affine transformation.

In geometry, the incircle or inscribed circle of a triangle is the largest circle that can be contained in the triangle; it touches the three sides. The center of the incircle is a triangle center called the triangle's incenter.

<span class="mw-page-title-main">Cubic equation</span> Polynomial equation of degree 3

In algebra, a cubic equation in one variable is an equation of the form $in which a is not zero.$

The great-circle distance, orthodromic distance, or spherical distance is the distance between two points on a sphere, measured along the great-circle arc between them. This arc is the shortest path between the two points on the surface of the sphere.

In geometry, hyperbolic angle is a real number determined by the area of the corresponding hyperbolic sector of xy = 1 in Quadrant I of the Cartesian plane. The hyperbolic angle parametrizes the unit hyperbola, which has hyperbolic functions as coordinates. In mathematics, hyperbolic angle is an invariant measure as it is preserved under hyperbolic rotation.

In mathematics, hyperbolic coordinates are a method of locating points in quadrant I of the Cartesian plane

In general relativity, Schwarzschild geodesics describe the motion of test particles in the gravitational field of a central fixed mass $that is, motion in the Schwarzschild metric. Schwarzschild geodesics have been pivotal in the validation of Einstein's theory of general relativity. For example, they provide accurate predictions of the anomalous precession of the planets in the Solar System and of the deflection of light by gravity.$

The Kerr–Newman metric describes the spacetime geometry around a mass which is electrically charged and rotating. It is a vacuum solution which generalizes the Kerr metric by additionally taking into account the energy of an electromagnetic field, making it the most general asymptotically flat and stationary solution of the Einstein–Maxwell equations in general relativity. As an electrovacuum solution, it only includes those charges associated with the magnetic field; it does not include any free electric charges.

In experimental particle physics, pseudorapidity, $, is a commonly used spatial coordinate describing the angle of a particle relative to the beam axis. It is defined as$

In geometric topology, Busemann functions are used to study the large-scale geometry of geodesics in Hadamard spaces and in particular Hadamard manifolds. They are named after Herbert Busemann, who introduced them; he gave an extensive treatment of the topic in his 1955 book "The geometry of geodesics".

A theoretical motivation for general relativity, including the motivation for the geodesic equation and the Einstein field equation, can be obtained from special relativity by examining the dynamics of particles in circular orbits about the Earth. A key advantage in examining circular orbits is that it is possible to know the solution of the Einstein Field Equation a priori. This provides a means to inform and verify the formalism.

In geometry, the trilinear coordinates $x : y : z$ of a point relative to a given triangle describe the relative directed distances from the three sidelines of the triangle. Trilinear coordinates are an example of homogeneous coordinates. The ratio $x : y$ is the ratio of the perpendicular distances from the point to the sides opposite vertices $A$ and $B$ respectively; the ratio $y : z$ is the ratio of the perpendicular distances from the point to the sidelines opposite vertices $B$ and $C$ respectively; and likewise for $z : x$ and vertices $C$ and $A$ .

In mathematics, sine and cosine are trigonometric functions of an angle. The sine and cosine of an acute angle are defined in the context of a right triangle: for the specified angle, its sine is the ratio of the length of the side that is opposite that angle to the length of the longest side of the triangle, and the cosine is the ratio of the length of the adjacent leg to that of the hypotenuse. For an angle $, the sine and cosine functions are denoted as and .$

The lateral earth pressure is the pressure that soil exerts in the horizontal direction. It is important because it affects the consolidation behavior and strength of the soil and because it is considered in the design of geotechnical engineering structures such as retaining walls, basements, tunnels, deep foundations and braced excavations.

In mathematics, a $space, where is a real number, is a specific type of metric space. Intuitively, triangles in a space are "slimmer" than corresponding "model triangles" in a standard space of constant curvature . In a space, the curvature is bounded from above by . A notable special case is; complete spaces are known as "Hadamard spaces" after the French mathematician Jacques Hadamard.$

In mathematics, the differential geometry of surfaces deals with the differential geometry of smooth surfaces with various additional structures, most often, a Riemannian metric.

Geographical distance or geodetic distance is the distance measured along the surface of the Earth, or the shortest arch length.

In hyperbolic geometry, the "law of cosines" is a pair of theorems relating the sides and angles of triangles on a hyperbolic plane, analogous to the planar law of cosines from plane trigonometry, or the spherical law of cosines in spherical trigonometry. It can also be related to the relativistic velocity addition formula.

References

M Bridson & A Haefliger - Metric Spaces Of Non-Positive Curvature , ISBN 3-540-64324-9

This metric geometry-related article is a stub. You can help Wikipedia by expanding it.

↑ Druţu, Cornelia; Kapovich, Michael (2018-03-28). "Geometric Group Theory". American Mathematical Society. Retrieved 2024-12-10.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] Druţu, Cornelia; Kapovich, Michael (2018-03-28). "Geometric Group Theory". American Mathematical Society. Retrieved 2024-12-10.

[1]

Comparison triangle

Contents

Definitions