Parallel (geometry): Difference between revisions

	Main Article	Discussion	Related Articles  [?]	Bibliography  [?]	External Links  [?]	Citable Version  [?]
	This editable Main Article is under development and subject to a disclaimer. [edit intro]

Straight railway tracks may be considered as segments of parallel lines, railway tracks with curves are parallel curves.

According to the common explanation two straight lines in a plane are said to be parallel (or parallel to each other) if they do not meet (or intersect), i.e., do not have a point in common.

This definition is correct if (silently) the "natural" (Euclidean) geometry is assumed.
In it, the explicit condition "in a plane" is necessary because in space two straight lines that do not intersect need not be parallel. Non-intersecting lines that do not belong to a common plane are called skew.

Important properties of the notion "parallel" in Euclidean geometry are:

• (Uniqueness) Given a line then through any point (not on it) there is a uniquely determined line parallel to the given one.
• (Equidistant lines) Parallel lines have constant distance.
  (This means, more precisely, that all distances from a point on one of them to the other line are the same.)
• (Transitivity) If among three distinct lines two pairs of lines are parallel then the third pair is also parallel.

Generalizations:

• Analoguously, in three-dimensional space two planes, or a line and a plane, are said to be parallel if they do not intersect.
  In this case, no additional condition is necessary because they always belong to the "same space". (This is different, of course, if, more generally (hyper-)planes in higher-dimensional spaces are considered.)
• Equidistant curves are called parallel curves.

Mathematical significance

The statement that, to a straight line, there is only one parallel through a point plays an important role in the development of geometry and mathematics in general. Euclid states it — somewhat disguiesed — in his Elements as his fifth (and last) postulate. Therefore it is usually called the Parallel Postulate or Parallel Axiom.

Since this statement is much less natural or evident than Euclid's other axioms and postulates, mathematicians of all periods tried to prove it from the other assumptions, but in vain. Only as late as the nineteenth century the reason became clear, namely, that it can be neither proven nor disproven. (Details.) The statement is independent of the other axioms.

This discovery led to the development of an alternative geometry, that of the non-Euclidean or hyperbolic plane in which, to a given line and a point not on the line, there are infintely many non-intersecting lines through this point, Among these lines — usually also called parallels &madash; there are two boundary lines, called horoparallels or critical parallels. Sometimes, only these two exceptional lines are called parallels while the other non-intersecting lines are called ultra parallel.

While Newton's classical mechanics is based on Euclidean geometry, Einstein's relativity theory showed that physical space — while locally Euclidean — is not Euclidean in the large.

Mathematical notation

In mathematical formulas, "is parallel to" is usually denoted by the symbol   ∥   (Unicode U+2225) — two parallel vertical lines — and its negation "is not parallel to" by   ∦   (Unicode U+2226).

Thus, for two straight lines f and g, and for four points A,B,C,D

${\displaystyle f\parallel g\qquad {\textrm {and}}\qquad AB\parallel CD}$

mean that the lines f and g, and the line segments determined by AB and CD, respectively, are parallel.

Binary relation

${\displaystyle \parallel }$ is a binary relation on the set of straight lines.

By definition, any line is parallel to itself.

It is an equivalence relation:

• ${\displaystyle {\textrm {(reflexivity)}}\quad \ g\parallel g}$
• ${\displaystyle {\textrm {(symmetry)}}\quad \ g_{1}\parallel g_{2}\Leftrightarrow g_{2}\parallel g_{1}}$
• ${\displaystyle {\textrm {(transitivity)}}\quad g_{1}\parallel g_{2}\quad {\textrm {and}}\quad g_{2}\parallel g_{3}\Rightarrow g_{1}\parallel g_{3}}$

The Parallel Axiom consists of the following two statements:

• For all points P and all lines g there is a parallel line h through P:

${\displaystyle (\forall g,P)(\exists h)P\in h,h\parallel g}$

and

• Any two lines parallel to g and through P are the same:

${\displaystyle P\in h_{1},h_{2}\quad {\textrm {and}}\quad h_{1}\parallel g,h_{2}\parallel g\Rightarrow h_{1}=h_{2}}$

One line may be parallel to any number of other lines, which all are parallel to one another. In mathematical notation, parallel entities are symbolized by ∥, i.e. two adjacent vertical lines. Writing PQ for a line connecting two different points P and Q, this means

${\displaystyle \left.{\begin{aligned}AB\parallel CD\\CD\parallel EF\\\end{aligned}}\right\}\,\Rightarrow \,AB\parallel EF}$

unless the lines AB and EF coincide. In other words, the relation "to be parallel or coincide" between lines is transitive and moreover, it is an equivalence relation.

Similarly two planes in a three-dimensional Euclidean space are said to be parallel if they do not intersect in any point. It can be proved that if they intersect in a point then they intersect in a line (or coincide). Writing PQR for a plane passing through three different point P, Q, and R, transitivity may be written as follows:

${\displaystyle \left.{\begin{aligned}ABC\parallel DEF\\DEF\parallel GHI\\\end{aligned}}\right\}\,\Rightarrow \,ABC\parallel GHI}$

unless the planes ABC and GHI coincide. In other word, the relation "to be parallel or coincide" between planes is also transitive (and moreover, an equivalence relation).