Cartesian coordinates: Difference between revisions

From Citizendium
Jump to navigation Jump to search
imported>Paul Wormer
No edit summary
imported>Paul Wormer
No edit summary
Line 1: Line 1:
{{subpages}}
{{subpages}}
In plane [[analytic geometry]], '''Cartesian coordinates''' are two real numbers specifying a point in a Euclidean plane (a 2-dimensional Euclidean point space, an [[affine space]] with distance). The coordinates are called after their originator Cartesius (the Latin name of [[René Descartes]]), who introduced them in 1637. In 3-dimensional analytic geometry, a point is given by three real numbers, also called Cartesian coordinates.  [[Image:Cartesian2 coordinates.png|right|thumb|350px|Fig. 1. Two-dimensional Cartesian coordinates of point ''P''.]]
In plane [[analytic geometry]], '''Cartesian coordinates''' are two real numbers specifying a point in a Euclidean plane (a 2-dimensional Euclidean point space, an [[affine space]] with distance). The coordinates are called after their originator Cartesius (the Latin name of [[René Descartes]]), who introduced them in 1637. In 3-dimensional analytic geometry, a point is given by three real numbers, also called Cartesian coordinates.   
 
==Two dimensions==
[[Image:Cartesian2 coordinates.png|right|thumb|350px|Fig. 1. Two-dimensional Cartesian coordinates of point ''P''.]]


In two dimensions the position of a point ''P'' in a plane can be specified by its distance from two lines intersecting at right angles, called axes. For instance, in Figure 1 two lines intersect each other at right angles in the point ''O'', the ''origin''. One axis is the line ''O–X'', the other ''O–Y'', and any point in the plane can be denoted by two numbers giving its perpendicular distances from ''O–X'' and from ''O–Y''.
In two dimensions the position of a point ''P'' in a plane can be specified by its distance from two lines intersecting at right angles, called axes. For instance, in Figure 1 two lines intersect each other at right angles in the point ''O'', the ''origin''. One axis is the line ''O–X'', the other ''O–Y'', and any point in the plane can be denoted by two numbers giving its perpendicular distances from ''O–X'' and from ''O–Y''.
Line 6: Line 9:
A general point ''P''  can be reached by traveling a distance ''x'' along a line  ''O–X'', and then a distance y along a line parallel to ''O–Y''. ''O–X'' is called the ''x-axis'', ''O–Y'' the ''y-axis'', and the point ''P'' is said to have Cartesian coordinates (''x'', ''y''). In the coordinate system shown, as is indicated in the diagram, the ''x''-coordinate is positive for points to the right of the ''y''-axis and negative for points to the left of this axis. The ''y''-coordinate is positive for points above the x-axis and negative for points below it. The coordinates of the origin are (0,0). One can introduce oblique axes and the position of a point may be defined in the same way: by its distance along lines parallel to the ''x'' and ''y'' axes. Sometimes these oblique coordinates also called "Cartesian", but more often the name is restricted to coordinates  related to orthogonal axes.   
A general point ''P''  can be reached by traveling a distance ''x'' along a line  ''O–X'', and then a distance y along a line parallel to ''O–Y''. ''O–X'' is called the ''x-axis'', ''O–Y'' the ''y-axis'', and the point ''P'' is said to have Cartesian coordinates (''x'', ''y''). In the coordinate system shown, as is indicated in the diagram, the ''x''-coordinate is positive for points to the right of the ''y''-axis and negative for points to the left of this axis. The ''y''-coordinate is positive for points above the x-axis and negative for points below it. The coordinates of the origin are (0,0). One can introduce oblique axes and the position of a point may be defined in the same way: by its distance along lines parallel to the ''x'' and ''y'' axes. Sometimes these oblique coordinates also called "Cartesian", but more often the name is restricted to coordinates  related to orthogonal axes.   


[[Image:Cartesian3 coordinates.png|left|thumb|350px|Fig. 2. Three-dimensional Cartesian coordinates of point ''P''.]]
==Three dimensions==
In  Figure 2 three (black) lines are shown in three-dimensional Euclidean space that intersect in a point ''O'', again called the origin. The lines are the ''x''-, ''y''-, and ''z''-axis. As in the two-dimensional case, the axes consist of two half-lines: a positive and a negative part of the axis.  
[[Image:Cartesian3 coordinates.png|left|thumb|350px|Fig. 2. Three-dimensional Cartesian coordinates of point ''P''. The frame is right-handed.]]
In  Figure 2 three (black) lines, labeled ''X'', ''Y'', ''Z'', are shown in three-dimensional Euclidean space. They intersect in a point ''O'', again called the origin. The lines are the ''x''-, ''y''-, and ''z''-axis. As in the two-dimensional case, the axes consist of two half-lines: a positive and a negative part of the axis. The frame is [[right-hand rule|right handed]], if we rotate the positive ''x''-axis to the positive ''y''-axis the rotation direction (by the [[corkscrew rule]])  is the direction of the positive ''z''-axis. In older literature and some special applications one may find a left-handed Cartesian set of axes, in which the ''x''- and the ''y''-axis are interchanged (or, equivalently, the ''z''-axis points downward).


The Cartesian coordinates of a point in 3-dimensional space are obtained by perpendicular projection. For example, in Figure 2 a point ''P'' is shown with projections on the positive parts of the axes, that is, all three coordinate of ''P'' are positive. The plane  ''ABCP'' is perpendicular to the ''x''-axis and ''B'' is the intersection of this axis with this plane. The length of ''O''–''B'' is the ''x''- coordinate of the point ''P''. The plane ''CDEP'' is perpendicular to the ''y''-axis and the length of ''O''–''D'' is the ''y'' coordinate of ''P''. Finally, ''AFEP'' is perpendicular to the ''z''-axis and the length of ''O''–''F'' is the ''z'' coordinate of ''P''. The planes through the origin ''O''  spanned by two of the axes are called the ''x''-''y'' plane (contains the surface ''BCDO'' of the rectangular block), the  ''x''-''z'' plane (contains the surface ''ABFO'' of the rectangular block), and the ''y''-''z'' plane (containing  ''DEFO''), respectively.
The Cartesian coordinates of a point in 3-dimensional space are obtained by perpendicular projection. For example, in Figure 2 a point ''P'' is shown with projections on the positive parts of the axes, that is, all three coordinate of ''P'' are positive. The plane  ''ABCP'' is perpendicular to the ''x''-axis and ''B'' is the intersection of the ''x''-axis with this plane. The length of ''O''–''B'' is the ''x''- coordinate of the point ''P''. The plane ''CDEP'' is perpendicular to the ''y''-axis and the length of ''O''–''D'' is the ''y'' coordinate of ''P''. Finally, ''AFEP'' is perpendicular to the ''z''-axis and the length of ''O''–''F'' is the ''z'' coordinate of ''P''.  


The planes through the origin ''O''  spanned by two of the axes are called the ''x''-''y'' plane (contains the surface ''BCDO'' of the rectangular block), the  ''x''-''z'' plane (contains the surface ''BAFO'' of the rectangular block), and the ''y''-''z'' plane (contains  ''DEFO''), respectively.
==Higher dimensions==
Although orthogonal axes are frequently introduced in Euclidean spaces of dimension ''n'' > 3, it is unusual to refer to these coordinates as "Cartesian",  more commonly they are called coordinates with respect to an orthogonal set of axes (briefly orthogonal, or rectangular,  coordinates).
Although orthogonal axes are frequently introduced in Euclidean spaces of dimension ''n'' > 3, it is unusual to refer to these coordinates as "Cartesian",  more commonly they are called coordinates with respect to an orthogonal set of axes (briefly orthogonal, or rectangular,  coordinates).

Revision as of 10:03, 14 November 2008

This article is developing and not approved.
Main Article
Discussion
Related Articles  [?]
Bibliography  [?]
External Links  [?]
Citable Version  [?]
 
This editable Main Article is under development and subject to a disclaimer.

In plane analytic geometry, Cartesian coordinates are two real numbers specifying a point in a Euclidean plane (a 2-dimensional Euclidean point space, an affine space with distance). The coordinates are called after their originator Cartesius (the Latin name of René Descartes), who introduced them in 1637. In 3-dimensional analytic geometry, a point is given by three real numbers, also called Cartesian coordinates.

Two dimensions

Fig. 1. Two-dimensional Cartesian coordinates of point P.

In two dimensions the position of a point P in a plane can be specified by its distance from two lines intersecting at right angles, called axes. For instance, in Figure 1 two lines intersect each other at right angles in the point O, the origin. One axis is the line O–X, the other O–Y, and any point in the plane can be denoted by two numbers giving its perpendicular distances from O–X and from O–Y.

A general point P can be reached by traveling a distance x along a line O–X, and then a distance y along a line parallel to O–Y. O–X is called the x-axis, O–Y the y-axis, and the point P is said to have Cartesian coordinates (x, y). In the coordinate system shown, as is indicated in the diagram, the x-coordinate is positive for points to the right of the y-axis and negative for points to the left of this axis. The y-coordinate is positive for points above the x-axis and negative for points below it. The coordinates of the origin are (0,0). One can introduce oblique axes and the position of a point may be defined in the same way: by its distance along lines parallel to the x and y axes. Sometimes these oblique coordinates also called "Cartesian", but more often the name is restricted to coordinates related to orthogonal axes.

Three dimensions

Fig. 2. Three-dimensional Cartesian coordinates of point P. The frame is right-handed.

In Figure 2 three (black) lines, labeled X, Y, Z, are shown in three-dimensional Euclidean space. They intersect in a point O, again called the origin. The lines are the x-, y-, and z-axis. As in the two-dimensional case, the axes consist of two half-lines: a positive and a negative part of the axis. The frame is right handed, if we rotate the positive x-axis to the positive y-axis the rotation direction (by the corkscrew rule) is the direction of the positive z-axis. In older literature and some special applications one may find a left-handed Cartesian set of axes, in which the x- and the y-axis are interchanged (or, equivalently, the z-axis points downward).

The Cartesian coordinates of a point in 3-dimensional space are obtained by perpendicular projection. For example, in Figure 2 a point P is shown with projections on the positive parts of the axes, that is, all three coordinate of P are positive. The plane ABCP is perpendicular to the x-axis and B is the intersection of the x-axis with this plane. The length of OB is the x- coordinate of the point P. The plane CDEP is perpendicular to the y-axis and the length of OD is the y coordinate of P. Finally, AFEP is perpendicular to the z-axis and the length of OF is the z coordinate of P.

The planes through the origin O spanned by two of the axes are called the x-y plane (contains the surface BCDO of the rectangular block), the x-z plane (contains the surface BAFO of the rectangular block), and the y-z plane (contains DEFO), respectively.

Higher dimensions

Although orthogonal axes are frequently introduced in Euclidean spaces of dimension n > 3, it is unusual to refer to these coordinates as "Cartesian", more commonly they are called coordinates with respect to an orthogonal set of axes (briefly orthogonal, or rectangular, coordinates).