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Scalene and Isosceles Partitions (SIP)
The scalene partition is a new simple construction for dividing --by means of compass and straightedge-- any line segment AB into n equal parts.
- See Fig. 1
- Given any line segment AB,
trough point Adraw a segment line CD
perpendicular to AB whose length is (n+1)/2
times the length CA. The length CA is
arbitrarily chosen.
- Find midpoint Pm of AB.
- Draw BC and BDand let the
line DPm cut BC at E.
- Trough point E draw EF
parallel to AB and EG parallel to CD.
- The line FG cuts AB at
point Pn, then :
APn = AB / n
And the line
segment AB can now be divided into n equal segments of length APn.
Take a look at Fig. 1. The Scalene
construction allows to find any segment of length AB/n without
constructing any other previous partitions of AB. For this reason
it is very interesting to compare this new Scalene partition with Proposition
9, Book 6 of Euclid's Elements.
In this way, in order to find the
partition AB/n of the line segment AB, Scalene
partition requires drawing seven (7) initial segments lines while Euclid's
partition requires only four (4) lines, however, in order to draw the auxiliary
segment line CD the Scalene partition requires only (n+1)/2
additional compass movements while Euclid's Proposition requires n
additional compass movements.
Considering that we are
exclusively talking about compass and straightedge, this comparison makes much
sense when n > 8, in such a case, Scalene Partition requires fewer
compass movements than Proposition 9, Book 6 of Euclid's Elements. Actually, this
compass-movements comparison should be made considering all the lines involved
in the construction. In this way, I hope the reader will be interested in doing
so for the following SIP Variation (Fig 1-1) :
Based on this, Scalene Partition becomes more
efficient than Proposition 9, Book VI of Euclid's Elements. Actually, I must
say tha in Euclid's Proposition 9 we could use only (n+1)/2
additional compass movements for constructing the auxiliary segment line, in
such a case both SIP and Euclid constructions are very similar, however, we are
asuming Euclid's proposition just as it was stated.
Given
any line segment AB, Isosceles partition is a new construction for finding
---by agency of compass and straightedge--- the following sequence of
partitions (See Fig. 3).
AB/n,
AB/(n+1), AB/(n+2), AB/(n+3), ...
See Fig.
2. Given any line segment AB draw
a segment line CD perpendicular to AB whose
midpoint is located at point A and its length is CD = 2CA.
The length CA is arbitrarily chosen. Given a starting point Pnin AB whose distance from A is :
APn = AB
/ n
Draw BC and
BD and let the line DPncut BC in E. Trough E draw
EF parallel to AB and EG parallel to CD.
The line FG cuts AB at point Pn+1, then :
APn+1 = AB / (n+1)
The line segment AB can now be divided
into n+1 equal segments.
·
(See Fig. 3)
·
By continuously repeating the above steps we
will find sequentially the points Pn, Pn+1, Pn+2
... whose corresponding distances from A are :
AB/n, AB/(n+1), AB/(n+2), AB/(n+3), ...
The Isosceles Partition.
In Fig. 3 draw the lines EPn+1,
IPn+2, MPn+3. Now, it is easy to prove that the
lines EPn+1 and BD are parallels. In the same way,
the lines IPn+2 and ED, the lines MPn+3
and ID, . . . and so on, are parallels. Based on
this, Isosceles partition (Fig 3) becomes as an extremely simple
method which only involves the construction of the aforesaid parallels, that is:
EPn+1 parallel to BD , IPn+2 parallel to ED , MPn+3
parallel to ID , and so on ...
One can see that Isosceles partition yields an unique
sequence involving both the even and odd partitions :
AB/3 , AB/4 , AB/5
, AB/6 , ... , AB/(n-1) , AB/n
Moreover, the most important fact is that Isosceles
Partition offers much more than the above sequence. It is a general method
which also permits ---with so much simplicity--- the generation of many
partition sequences, including FIBONACCI (Fig 4),
even-odd-denominator sequences and other higher order sequences.
.The Isosceles-Fibonacci Partition. Published by: Journal of Transfigural
Mathematics, Berlin, 1997.
Notice that the partition sequence follows the Fibonacci sequence.
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