| T.R | Title | User | Personal
Name | Date | Lines |
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| 627.1 | I'm confused by your question | ENGINE::ROTH | | Thu Dec 11 1986 09:22 | 8 |
| I don't think your problem is really well posed, since a geometry
is really defined in terms of transformations among lines, points
and so on and your question thus seems circular.
You could assume the line to be a geodesic, given the group of
transformations that make up the geometry under consideration...
- Jim
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| 627.2 | I hope this helps . . . | THEBUS::KOSTAS | Wisdom is the child of experience. | Thu Dec 11 1986 09:50 | 22 |
| re. .1
If one body is abraded against another, turning and sliding in all
possible ways, and then the first against a third, and the second
against a third, until each pair fit perfectly, the three surfaces
will be planes. If again the three bodies are abraded so as to produce
a second plane intersecting the first, the edge where they meet will be
a straight line. This is a tedious and not very practical way to make
sure of a straight line.
We generally make use of light rays to test the straightness of a line.
We sight along the edge of a ruler, and correct its edge until the whole
edge can be seen as a point. But this is an optical method, not a geometrical
method: and it may not produce a Euclidean straight line if the light path is
curved as in a space described by Einstein.
Until the year 1864 no striclty geometric method was known by which a
straight line could be generated. Then Peaucellier invented a linkage.
Since then other linkages have been devised that accomplish the same purpose.
-kgg
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| 627.3 | more confused | CACHE::MARSHALL | hunting the snark | Thu Dec 11 1986 17:08 | 22 |
| seems that the optical method is the most "geometric". The "abrasion"
method you describe is how those rulers are made in the
first place, and it is not all that tedious.
If the objection to using light is the curvature of space, well
then, the ruler will also be equally curved. Relativity showed that
a ruler that was "straight" in flat space, would still be "straight"
in curved spce. That is, in both cases it would produce the shortest
distance between two points.
One common definition of a straight-line is the "taut string".
Light is really very very good at making straight lines.
What is a "linkage"? (I assume you do not mean a mechanical linkage)
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| 627.4 | | TLE::BRETT | | Thu Dec 11 1986 22:05 | 11 |
| There are lots of spaces where you can NOT draw a straight line
between two points, because the space is "not connected".
An obvious example is the set of points {(x,y) : x<0 or x>1} with
two points that you can't draw ANY line between (-1,0) and (2,0),
yet alone a "straight" one.
Thats why the phrase "Euclidean space" exists - there are LOTS of
other spaces.
/Bevin
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| 627.5 | | MODEL::YARBROUGH | | Fri Dec 12 1986 13:42 | 5 |
| If I recall, Euclid based his geometry on basic tools such as a
straightedge and compass. The straightedge was postulated, not constructed;
it was just assumed that such a beast existed. So is the question how to
construct a straightedge, or how to use one? I, too, am confused by the
question as stated.
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| 627.6 | A "linkage" | CLT::GILBERT | eager like a child | Fri Dec 12 1986 17:29 | 10 |
| A "linkage" is a mechanical device that can be used to construct
a straight line. It consists of about 6 rods connected together
at their ends (in some arrangement that escapes me), so that the
rods may rotate w.r.t. each other at these connections. Two ends
are 'fixed', and when the linkage is 'moved', the end of one of
the rods moves in a straight line.
Actually, the linkage I've just described is constrained to lie
in a plane -- two such linkages can be combined to trace a line
if you don't happen to have a flat plane available.
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| 627.7 | I was afraid it would be mechanical | CACHE::MARSHALL | hunting the snark | Fri Dec 12 1986 23:35 | 17 |
| re .6:
Mechanical linkage, eh? I have serious doubts that that will produce
a line that is "straighter" than a beam of light. Also, put that
linkage in a curved space and it'll draw curved lines.
re earlier:
okay I assumed that we would be referring to physical spaces and
not mathematical spaces. In which case there is Euclidean or "flat"
space, Reimann or hyperbolic space, and spherical space.
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| 627.8 | Peaucellier's linkage (1864) . . . | CASSAN::KOSTAS | Wisdom is the child of experience. | Sat Dec 13 1986 20:43 | 58 |
| I regret for not beeing able to peply earlier due to system
availability.
Until the year 1864 no striclty geometric method was known by which a
straight line could be generated. Then Peaucellier invented the
linkage described here (is this mechanical? see for your self).
Since then other linkages have been devised that accomplish the same
purpose.
A and B are fixed points, separated by a distance r. At B is pivoted
a link whose length is BC = r. At C is pivoted one corner of a rhombus,
formed by four links, and of length j. Opposite corners of the rhombus
are connected to A, by links of length AM = h.
Figure 1. To be supplied some other time. (long distance communications
do not allow slow drawing)
Taking O as the center of the rhombus, we have
AC = AO - CO
AP = AO + CO
=> AP * AC = (AO)^2 - (CO)^2
= (h^2 - x^2) - (j^2 - x^2)
taking MO = x
= h^2 - j^2
Observe that
h^2 - j^2 is a constant, and we may call it 2rk.
Now AC = 2r cos (BAP), and AP = 2rk/AC, hence
AP = k / cos (BAP)
This equation shows that P is located on the perpendicular to AB
whose foot is at distance k from A.
P
.
/|
/ |
/ |
/ |
/ |
/ B |
A .____._______|
k
Figure 2.
Accordingly the path of P is a straight line.
Enjoy,
Kostas G.
p.s. Figure 1 to be supplied soon.
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| 627.9 | | BEING::POSTPISCHIL | Always mount a scratch monkey. | Sun Dec 14 1986 13:35 | 7 |
| Re .8:
Your demonstration that the linkage makes a straight line uses
Euclidean geometry.
-- edp
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