| A figure is a set of points. |
| Space is the set of all points. |
| Three or more points are collinear if and only if they are on the same line. |
| Four or more points are coplanar if and only if they are in the same plane. |
When all points in space are collinear, the geometry is one-dimensional. When all points in space are coplanar, the geometry is two-dimensional (2D) or plane geometry. Common figures we will study, such as squares, circles, and triangles are two-dimensional. Other figures, such as spheres, boxes, cones, and other tangible objects do not lie in one plane and are three-dimensional or 3D. The study of these is called solid geometry.
What our undefined terms really mean depends on which set of axioms or postulates we choose. Historically, axioms were self-evident truths, hence the word postulate, meaning assumption is now more commonly used. The postulates we will use correspond with Euclidean Geometry and fit both the synthetic and coordinate geometries introduced above, but not discrete geometry nor graph theory.
Euclidean Geometry is so named because is was well established in the set of thirteen books called Elements written by Euclid about 300 B.C. These books also dealt with other areas of mathematics. It is widely believed that Euclid summarized much of the known mathematics of his time. His geometry starts with five assumptions (requests), the fifth becoming very controversial by the early 1800's. Several online versions exist, including a wonderful color version from the early 1800's.
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Euclid's Fifth Postulate: Through a point not on a line, one and only one line can be drawn parallel to that line. |
Rejecting Euclid's Fifth Postulate leads one to Non-euclidean Geometries. A substantial portion of standard geometry can be developed without it and is termed Neutral Geometry. Adapting variations of Euclid's Fifth Postulate leads to several types of Geometries involving positively or negatively curved surfaces. A plane or cylinder has zero curvature. A sphere has positive curvature. A saddle has negative curvature. On a sphere no line parallel can be drawn through a point outside a line. On a saddle, more than one such parallel line can be drawn. The geometry of a saddle shaped surface is known as hyperbolic geometry (from the Greek to exceed). The geometry of a sphere required additional changes to the usual axioms because betweenness is no longer meaningful and must be replaced with separation. This is known as Elliptic Geometry. The last geometry we will discuss is Reimannian Geometry. Its full development requires calculus, which is beyond the scope of these lessons. This geometry was popularized by Albert Einstein when he developed his theory of General Relativity with the notion that space is curved by the presence of mass.
Euclid is known as the father of geometry. When Ptolomy asked if there was an easier way to learn geometry Euclid replied: "There is no royal road to Geometry."
There are other geometry between incidence and the coordinatized Euclidean version with least upper bound. Just ask the author sometime and he might show you the book he is typing.... All in all, it takes hundreds of pages to cover the ground covered by the point-line-plane postulate given below! One geometry not cover there (yet) is projective geometry which has an important dualism between points and lines. Compare the following: 2 points determine a line; and 2 lines determine a point.
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The first assumption is sometimes stated simply as: two points determine a line. It should be clear that the Unique Line Assumption does not apply to lines in discrete geometry (part of different lines near each other) or graph theory (more than one arc connecting two nodes). The Number Line Assumption also does not apply to lines in graph theory since it guarantees infinitely many points. These postulates herd us quickly down the road toward the development of Euclidean geometry. Many interesting geometries could be investigated if we started with much simpler postulates. The number line assumption in particular immediately gives us measurement, distance, betweenness, and infinite points.
We can now prove our first theorem by using the Unique Line Assumption. (See book for details.)
| Theorem: Two different lines intersect in at most one point. |
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Two coplanar lines m and n are
parallel, written m||n, if and only if they have no points in common (or they are identical). |
Note: this definition of parallel is typical for our textbook but is often at odds with what students are taught in middle school. It is an example of an inclusive definition. Along a similar vein, a quadrilateral which happens to be square is still a rectangle. An equilateral triangle is still isosceles. A square is still a trapezoid. Teresa Heinz-Kerry is still a Heinz. Although standardized tests and contests tend to avoid these ambiguities, one must be on the lookout for such problems!
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Warning our geometry textbook only motivates betweenness using
numbers on a number line. It neither defines it nor adopts an axiom to develop it. |
Below are four typical axioms of betweenness. A*B*C means point B is between point A and point C.
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The segment (or line segment) with endpoints
A and B, denoted
![[segment AB]](seg1ab.gif) ,
is the set consisting of the distinct points A and B
and all points between A and B.
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The ray with endpoint A and containing a second point B,
denoted ![[ray AB]](rayab1.gif) ,
consists of the points on
and all points for which B is between each of them and A.
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and
![[ray AC]](rayac1.gif) are opposite rays
if and only if A is between B and C.
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Please note that our segments and rays are closed—they include their endpoints. In other geometries, segments and rays could be open (or half open) and exclude their endpoint(s). Ultimately, another axiom, the least upper bound axiom is needed to deal with this. Three more important assumptions are known as the Distance Postulate.
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Distances are positive values and the symbol for absolute value: |-10| = 10 is utilized above. The distance between two points A and B is written AB. You cannot multiply points, so AB always represents the distance between, and never their product. Because distance is always positive, AB = BA. The term directed distance is sometimes uses to convey not only magnitude, but also the direction. It is thus a vector instead of a scalar quantity.
Please note carefully the differences among
distance AB, segment
, ray
, and line
![[line AB]](line2ab.gif) ,
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Although mathematicians don't often draw in perspective,
the concept and terminology are important.
A perspective drawing gives a two-dimensional object
a feeling of depth. Parallel lines now meet in the distance
at a vanishing point. Often one thinks of the
artist's or observer's eye as this vanishing point and sketches
lines of sight to connect them.
Objects can be drawn in one- two- or three-point perspective,
depending on how many vanishing points are used.
Parallel horizontal and vertical lines go to their own vanishing point,
depending on their relationship to each other.
Multiple vanishing points should line up on the vanishing line
which corresponds with the horizon line at
the height of the observer's eye.
Mathematicians typically draw non-perspective drawings,
utilizing dashed or dotted hidden lines to indicate
parts not normally seen. Compare the two pictures shown
above left and below. Find the vanishing points for the
drawing below.
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