Euclidean plane: Difference between revisions

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As is known from Euclidean geometry lines can be drawn between points and different geometric figures (triangles, squares, etc.) can be constructed. A geometric figure can be translated and rotated without change of shape. Such a map is called a ''[[rigid motion]]'' of the figure. The totality of rigid motions form a [[group]] of infinite order, the [[Euclidean group]] in two dimensions, often written as ''E''(2).   
As is known from Euclidean geometry lines can be drawn between points and different geometric figures (triangles, squares, etc.) can be constructed. A geometric figure can be translated and rotated without change of shape. Such a map is called a ''[[rigid motion]]'' of the figure. The totality of rigid motions form a [[group]] of infinite order, the [[Euclidean group]] in two dimensions, often written as ''E''(2).   


Formally, the Euclidean plane is a 2-dimensional [[affine space]] with [[inner product]].
Formally, the Euclidean plane is a 2-dimensional [[affine space]] with [[inner product]].[[Category:Suggestion Bot Tag]]

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The Euclidean plane is the plane that is the object of study in Euclidean geometry (high-school geometry). The plane and the geometry are named after the ancient-Greek mathematician Euclid.

The Euclidean plane is a collection of points P, Q, R, ... between which a distance ρ is defined, with the properties,

  1. ρ(P,Q) ≥ 0 and ρ(P,Q) = 0 if and only if P = Q
  2. ρ(P,Q) = ρ(Q,P)
  3. ρ(P,Q) ≤ ρ(P,R) + ρ(R,Q) (triangular inequality).

As is known from Euclidean geometry lines can be drawn between points and different geometric figures (triangles, squares, etc.) can be constructed. A geometric figure can be translated and rotated without change of shape. Such a map is called a rigid motion of the figure. The totality of rigid motions form a group of infinite order, the Euclidean group in two dimensions, often written as E(2).

Formally, the Euclidean plane is a 2-dimensional affine space with inner product.