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betweenness in rays
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(Definition)
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Let $S$ be a linear ordered geometry. Fix a point $p$ and consider the pencil $\Pi(p)$ of all rays emanating from it. Let $\alpha\neq\beta \in\Pi(p)$ . A point $q$ is said to be an interior point of $\alpha$ and $\beta$ if there are points $s\in\alpha$ and $t\in\beta$ such that
- $q$ and $s$ are on the same side of line $\line{pt}$ , and
- $q$ and $t$ are on the same side of line $\line{ps}$ .
A point $q$ is said to be between $\alpha$ and $\beta$ if there are points $s\in\alpha$ and $t\in\beta$ such that $q$ is between $s$ and $t$ . A point that is between two rays is an interior point of these rays, but not vice versa in general. A ray $\rho\in\Pi(p)$ is said to be between rays $\alpha$ and $\beta$ if there is an interior point of $\alpha$ and $\beta$ lying on $\rho$ .
Properties
- Suppose $\alpha,\beta,\rho\in\Pi(p)$ and $\rho$ is between $\alpha$ and $\beta$ . Then
- any point on $\rho$ is an interior point of $\alpha$ and $\beta$ ;
- any point on the line containing $\rho$ that is an interior point of $\alpha$ and $\beta$ must be a point on $\rho$ ;
- there is a point $q$ on $\rho$ that is between $\alpha$ and $\beta$ . This is known as the Crossbar Theorem, the two ``crossbars'' being $\rho$ and a line segment joining a point on $\alpha$ and a point on $\beta$ ;
- if $q$ is defined as above, then any point between $p$ and $q$ is between $\alpha$ and $\beta$ .
- There are no rays between two opposite rays.
- If $\rho$ is between $\alpha$ and $\beta$ , then $\beta$ is not between $\alpha$ and $\rho$ .
- If $\alpha,\beta\in\Pi(p)$ has a ray $\rho$ between them, then $\alpha$ and $\beta$ must lie on the same half plane of some line.
- The converse of the above statement is true too: if $\alpha,\beta\in\Pi(p)$ are distinct rays that are not opposite of one another, then there exist a ray $\rho\in\Pi(p)$ such that $\rho$ is between $\alpha$ and $\beta$ .
- Given $\alpha,\beta\in\Pi(p)$ with $\alpha\neq\beta$ and $\alpha\neq-\beta$ . We can write $\Pi(p)$ as a disjoint union of two subsets:
- $A =\lbrace \rho\in\Pi(p)\mid \rho\mbox{ is between }\alpha\mbox{ and }\beta\rbrace$ ,
- $B=\Pi(p)-A$ .
Let $\rho,\sigma\in\Pi(p)$ be two rays distinct from both $\alpha$ and $\beta$ . Suppose $x\in\rho$ and $y\in\sigma$ . Then $\rho,\sigma$ belong to the same subset if and only if $\overline{xy}$ does not intersect either $\alpha$ or $\beta$ .
- 1
- D. Hilbert, Foundations of Geometry, Open Court Publishing Co. (1971)
- 2
- K. Borsuk and W. Szmielew, Foundations of Geometry, North-Holland Publishing Co. Amsterdam (1960)
- 3
- M. J. Greenberg, Euclidean and Non-Euclidean Geometries, Development and History, W. H. Freeman and Company, San Francisco (1974)
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"betweenness in rays" is owned by CWoo. [ full author list (2) ]
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(view preamble | get metadata)
See Also: angle, ray
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interior point, between rays, between two rays, crossbar theorem |
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Cross-references: intersect, subsets, disjoint union, opposite, converse, half plane, lie on, opposite rays, line segment, line, properties, lying on, side of line, rays, pencil, point, fix, linear ordered geometry
There are 3 references to this entry.
This is version 3 of betweenness in rays, born on 2005-10-27, modified 2007-06-22.
Object id is 7449, canonical name is BetweennessInRays.
Accessed 6741 times total.
Classification:
| AMS MSC: | 51G05 (Geometry :: Ordered geometries ) | | | 51F20 (Geometry :: Metric geometry :: Congruence and orthogonality) |
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Pending Errata and Addenda
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