Parallel (geometry): Difference between revisions

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[[Image:Rail tracks @ Coina train station 04.jpg|thumb|250px|alt=Picture of railroad tracks.|Railroad tracks must be parallel to each other or else the train will come off the track like this one in [[Portugal]].]]
[[Image:Rail tracks @ Coina train station 04.jpg|thumb|250px|alt=Picture of railroad tracks.|Railroad tracks must be parallel to each other or else trains will derail.]]
In [[Euclidean geometry]]:
In [[Euclidean geometry]] two '''parallel''' (symbolized by two adjacent vertical lines '''∥''') lines in a [[Plane (geometry)|plane]] do not cross. Two geometric entities (lines or planes) are said to be '''parallel''' if they do not [[intersect_(geometry)|intersect]] anywhere, that is, if they do not have a single point in common.  Thus, two [[line_(geometry)|lines]] are parallel if they belong to the same plane and do not cross at any [[point_(geometry)|point]], not even at infinity.
More than one line may be parallel to any number of other lines, which all are parallel to one another. In other word, parallel lines satisfy a transitivity relation. Writing ''PQ'' for a line connecting two different points ''P'' and ''Q'', this means
:<math>
\left.
\begin{align}
AB \parallel CD \\
CD \parallel EF \\
\end{align}
\right\}\,\Rightarrow\, AB \parallel EF
</math>


'''Parallel''' (symbolized by two adjacent vertical lines '''∥''') are two lines on a flat [[Plane (geometry)|plane]] that never meet. Two geometric entities are said to be '''parallel''' if they do not [[intersect_(geometry)|intersect]] if projected to infinity. More than one element may be parallel to any number of other elements, which would all be parallel to one another.
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 that they intersect in a line.  Writing ''PQR'' for a plane passing through three different point ''P'', ''Q'', and ''R'', parallellity of planes is a transitivity relation that may be written as follows
 
:<math>
Thus two [[line_(geometry)|lines]] are parallel if they do not cross at any [[point_(geometry)|point]] on a flat [[Plane (geometry)|plane]]. Similarly two [[plane_(geometry)|planes]] are said to be parallel if they do not intersect at any line.
\left.
 
\begin{align}
The following demonstrates parallel lines:
ABC \parallel DEF \\
  If a line AB is parallel to CD
DEF \parallel GHI \\
and AB is parallel to EF
\end{align}
then CD is parallel to EF
\right\}\,\Rightarrow\, ABC \parallel GHI
 
</math>
The following demonstrates parallel planes:
If a plane ABC is parallel to DEF  
and ABC is parallel to GHI
then ABC is parallel to GHI

Revision as of 11:04, 25 March 2010

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Picture of railroad tracks.
Railroad tracks must be parallel to each other or else trains will derail.

In Euclidean geometry two parallel (symbolized by two adjacent vertical lines ) lines in a plane do not cross. Two geometric entities (lines or planes) are said to be parallel if they do not intersect anywhere, that is, if they do not have a single point in common. Thus, two lines are parallel if they belong to the same plane and do not cross at any point, not even at infinity. More than one line may be parallel to any number of other lines, which all are parallel to one another. In other word, parallel lines satisfy a transitivity relation. Writing PQ for a line connecting two different points P and Q, this means

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 that they intersect in a line. Writing PQR for a plane passing through three different point P, Q, and R, parallellity of planes is a transitivity relation that may be written as follows