Examples of groupsSome elementary examples of groups in mathematics are given on Group (mathematics). Further examples are listed here. Dihedral group of order 6 Consider three colored blocks (red, green, and blue), initially placed in the order RGB. Let a be the operation "swap the first block and the second block", and b be the operation "swap the second block and the third block". We can write xy for the operation "first do y, then do x"; so that ab is the operation RGB → RBG → BRG, which could be described as "move the first two blocks one position to the right and put the third block into the first position".
Groupe topologiqueEn mathématiques, un groupe topologique est un groupe muni d'une topologie compatible avec la structure de groupe, c'est-à-dire telle que la loi de composition interne du groupe et le passage à l'inverse sont deux applications continues. L'étude des groupes topologiques mêle donc des raisonnements d'algèbre et de topologie. La structure de groupe topologique est une notion essentielle en topologie algébrique. Les deux axiomes de la définition peuvent être remplacés par un seul : Un morphisme de groupes topologiques est un morphisme de groupes continu.
Linearly ordered groupIn mathematics, specifically abstract algebra, a linearly ordered or totally ordered group is a group G equipped with a total order "≤" that is translation-invariant. This may have different meanings. We say that (G, ≤) is a: left-ordered group if ≤ is left-invariant, that is a ≤ b implies ca ≤ cb for all a, b, c in G, right-ordered group if ≤ is right-invariant, that is a ≤ b implies ac ≤ bc for all a, b, c in G, bi-ordered group if ≤ is bi-invariant, that is it is both left- and right-invariant.
Groupe parfaitEn théorie des groupes (mathématiques), un groupe est dit parfait s'il est égal à son dérivé. Dans ce qui suit, le dérivé d'un groupe G sera noté D(G). Si un groupe G est parfait, l'image de G par un homomorphisme est un groupe parfait. En particulier, tout groupe quotient d'un groupe parfait est parfait.En effet, si f est un homomorphisme d'un groupe G (quelconque) dans un autre groupe, on a toujours D(f(G)) = f(D(G)). Si un groupe parfait G est sous-groupe d'un groupe H, il est contenu dans le dérivé de H.
Quadrature du cerclevignette|Le carré de côté a la même aire que le cercle de rayon 1. La quadrature du cercle est un problème classique de mathématiques apparaissant en géométrie. Il fait partie des trois grands problèmes de l'Antiquité, avec la trisection de l'angle et la duplication du cube. Le problème consiste à construire un carré de même aire qu'un disque donné à l'aide d'une règle et d'un compas (voir Nombre constructible). La quadrature du cercle nécessiterait la construction à la règle et au compas de la racine carrée du nombre π, ce qui est impossible en raison de la transcendance de π.
Local homeomorphismIn mathematics, more specifically topology, a local homeomorphism is a function between topological spaces that, intuitively, preserves local (though not necessarily global) structure. If is a local homeomorphism, is said to be an étale space over Local homeomorphisms are used in the study of sheaves. Typical examples of local homeomorphisms are covering maps.
Real projective lineIn geometry, a real projective line is a projective line over the real numbers. It is an extension of the usual concept of a line that has been historically introduced to solve a problem set by visual perspective: two parallel lines do not intersect but seem to intersect "at infinity". For solving this problem, points at infinity have been introduced, in such a way that in a real projective plane, two distinct projective lines meet in exactly one point.
Constructible polygonIn mathematics, a constructible polygon is a regular polygon that can be constructed with compass and straightedge. For example, a regular pentagon is constructible with compass and straightedge while a regular heptagon is not. There are infinitely many constructible polygons, but only 31 with an odd number of sides are known. Some regular polygons are easy to construct with compass and straightedge; others are not.
Projectively extended real lineIn real analysis, the projectively extended real line (also called the one-point compactification of the real line), is the extension of the set of the real numbers, , by a point denoted ∞. It is thus the set with the standard arithmetic operations extended where possible, and is sometimes denoted by or The added point is called the point at infinity, because it is considered as a neighbour of both ends of the real line. More precisely, the point at infinity is the limit of every sequence of real numbers whose absolute values are increasing and unbounded.
Homeomorphism groupIn mathematics, particularly topology, the homeomorphism group of a topological space is the group consisting of all homeomorphisms from the space to itself with function composition as the group operation. Homeomorphism groups are very important in the theory of topological spaces and in general are examples of automorphism groups. Homeomorphism groups are topological invariants in the sense that the homeomorphism groups of homeomorphic topological spaces are isomorphic as groups.
