MATHEMATICS AND ORIGAMI

(Dana P.) #1
Mathematics and Origami

In the argentic rectangle of fig. 2, and because of its own definition, angles α and γ will ap-
pear in the four corresponding right triangles. That is, in the straight angle in O containing the
media parallel of the rectangle, are occupied 2γ degrees.

Let ́s figure out the difference d = 180 – 2 γ
Looking at Fig. 1 we have:
360 = 10 γ ; 180 = 5 γ
so it is:
d= 5 γ− 2 γ= 3 γ
What means that around the center of the rectangle we can trace 10 γ angles by pleat
folding of the four we began with.
Let ́s see now what is in Fig. 3. Broken line AOBC determines in O and B the β angles
of a pentagon whose diagonal is OC (Ang. OBC = Ang. BOF = 3γ).
Vertex D is the symmetric of C with respect to the bisector of ε, and E is the symmetric
of D with respect to the bisector of Ang. OBC.
Fig. 4 shows what the resultant stellate pentagon looks like. We may note that the center
O of the rectangle becomes one of the points of the stellate pentagon.

11.2 STELLATE HEPTAGON


Begin with the convex heptagon of Fig. 1 making the partial folds of its diagonals. To
fold-stellate that polygon we would have to be able to gather the paper of triangles like KMN.
Since that is not possible in a flat single paper figure, we have to yield some gatherable paper
by reducing the size of the given heptagon while producing a twist on it.
To produce that torsion we need first to build the small heptagon of side AB (Fig. 2), in
this way:


  • Fold over each side:

    • Its perpendicular bisector.

    • The perpendicular bisector of half a side (in the figure, anticlockwise sequence).



  • The successive intersections of those perpendicular bisectors produce points like A,
    B and, in consequence, the complete heptagon.


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F

O

E

B

C

B

C
D

A A

O

F
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