The Geometry of Stars

The Geometry of Stars
© 2013 Tofique Fatehi
Page 1
THE GEOMETRY OF STARS
May 10, 2013 Tofique Fatehi
tofiquef@yahoo.com
http://tofique.fatehi.us
PRELUDE
“Why ask for the moon, when we have the stars?”
- Tony Brent
In this essay I try to categorize star-shaped Figures, so that
they can be systematically classified and documented. Not
much work seems to have been done in this field, and so, I
take full liberty to venture into it, using my own descriptions
and evolving my own terminology, where none are clearly
available.
STARS
Just as a plane figure of “n” sides is called a polygon, we may term a plane n-pointed star a
“polygram”. This term is not in general use, and may even have a completely different meaning in
some other branch of science. Depending on the value of “n”, many of these figures have specific
names. Polygons are named pentagon, hexagon and so on, and polygrams are named pentagram,
hexagram and so on. These figures are said to be regular if all sides and all corresponding angles
are equal.
Acknowledgment
This is to acknowledge
with thanks the
meticulous effort put in by
Parul Vijay Patil in the
preparation of all the
drawings for this essay.

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Figure 1a shows a regular hexagon (a six-sided polygon). If all the sides of the hexagon are
extended on both sides, it produces a six-pointed star (as in Figure 1b). This star is called a
hexagram.
Figure 1a - Hexagon Figure 1b - Hexagram
Figure 2a shows a regular pentagon (a five-sided polygon). This produces a five-pointed star if all
the sides are extended on both sides (as in Figure 2b). This star is called a pentagram. It is also
sometimes called a pentalpha or a pentangle.
Figure 2a – Pentagon Figure 2b - Pentagram

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The pentagram can be drawn fully, without lifting the pen from the paper (unicursally), and
without breaking any side. The hexagram cannot be so drawn - at least not without breaking any
side. In fact, the hexagram actually is composed of two interlaced equilateral triangles. Stars
which can be drawn unicursally may be termed “prime”. Stars which are composed of interlaced
figures may be termed “composite”.
Figure 4 shows a square and a triangle (four-sided and three-sided polygons). For these figures,
even if the sides are extended indefinitely, no star is produced. It may therefore be concluded that
the minimum number of points required to form a star is five.
Figure 4a – Square Figure 4b – Triangle
Now let's take a look at a regular septagon (a seven-sided polygon). This is also called a heptagon.
This is shown in Figure 5a. As before, extending all the sides both ways produces a seven-pointed
It may be pointed out that there
does exist a unicursal hexagram
(much used in witchcraft), but
then, that does not belong to any
class of our present study. Just
for the record, this is shown in
Figure 3.
Figure 3

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star, called a septagram or heptagram, shown in Figure 5b. It does not end here. If the sides are
extended still further, another seven-pointed star is produced (as in Figure 5c). This also has the
same name: septagram (or heptagram).
Figure 5a - Septagon Figure 5b -Septagram of the First Order
Figure 5c -Septagram of the Second Order
So now, we have two different seven-pointed stars, both regular, and both prime, and yet both
different. We need to differentiate between these two forms. We do so by inventing an “order”.
We shall call the first star (in Figure 5b) a “septagram of the first order”, and the second star (in
Figure 5c) a “septagram of the second order”. It may be stated that there is no second order
pentagram or hexagram. It is worth noting that any polygon can be considered a zero-order
polygram.

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An unspecified order of any star may be designated as “m”. At this point, we may introduce a
notation to specify any star. We will use the notation “*n^m” to specify an “n” pointed star of
order “m”. This will become clearer as we proceed.
There is a simpler way to draw the polygrams in a more manageable manner.
SIMPLIFYING CONSTRUCTION OF STARS
Suppose our target is an n-sided figure. First draw a circle (of any diameter, that's immaterial).
Mark “n” points on the circumference, all equidistant. Number these points serially from 1 to “n”,
(clockwise or otherwise, that's immaterial). If all these points (starting from point 1) are
connected serially by a line, we end up returning to the starting point, and we get an “n”-sided
regular polygon.
If we connect these points by a line, not to next point, but, to the next-but-one point, (that is, every
alternate point) we will return back to the starting point. If we have covered all the points, we
would have got an n-pointed prime polygram. However, it may so happen that we return to the
starting point, without yet covering all the points. This will be an indication that the polygram is
not prime, but composite, consisting of two (or more) interlaced figures, of which we have one
figure.
Next, we start from a free point adjacent to the starting point of the first figure, and complete the
circuit, following the same rule (of connecting the next-but-one point). If there are still any
uncovered points, we repeat the process until all “n” points are covered. We would then have got
an n-pointed composite polygram. This star, prime or composite, would be a first-order star.
Figure 6 – Construction of a Prime Polygram Figure 7 – Construction of a Composite
Polygram

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If the points are connected by a line to the next-but-two point, we get a prime star if we return to
the starting point after covering all the points. Otherwise, if some of the points remain uncovered,
then, following a procedure similar to the one in the previous paragraph, we get a composite star.
Either prime or composite, this would be a second-order star.
All the higher ordered polygrams can also be similarly defined.
SIGNATURES
This sequence of connecting the points may be termed the “signature” of the polygon or
polygram. It may be noted that each and every figure has its own unique signature.
Thus, the signature of a pentagon is (1 2 3 4 5 1), and the signature of a pentagram is (1 3 5 2 4 1).
The signatures of all polygons are self-evident (sequential, from 1 to “n” and back to 1) and so
need no further consideration. Those of the polygrams are not so obvious, and hence are dealt
with further.
The signature of the hexagram is (1 3 5 1) (2 4 6 2). Notice that the hexagram is a composite
polygram consisting of two interlaced triangles. Hence we have the two groups of bracketed
figures. This is the only star which has no prime figure.
Figure 6 –Prime pentagram *5^1,
with signature (1 3 5 2 4 1)
Figure 7 –Composite hexagram *6^1,
with signature (1 3 5 1) (2 4 6 2)

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There are two septagrams, both prime. One is of the first order and the other is of the second
order. The signature of the first order septagram is (1 3 5 7 2 4 6 1). The signature of the second
order septagram is (1 4 7 3 6 2 5 1).
Figure 8 – Septagram *7^1,
with signature (1 3 5 7 2 4 6 1)
Figure 9 – Septagram *7^2,
with signature (1 4 7 3 6 2 5 1)
There are two octagrams. The first-order octagram is composite, being composed of two
interlaced squares, and the second-order octagram is prime.
Figure 10 – Octagram *8^1,
with signature (1 3 5 7 1) (2 4 6 8 2)
Figure 11 - Octagram *8^2,
with signature (1 4 7 2 5 8 3 6 1)

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A nine-pointed star is called a nonagram (or enneagram), and has three configurations. The first
and third order stars are prime and the second order star is composite and is composed of three
equilateral triangles.
Figure 12 - Nonagram *9^1,
with signature (1 3 5 7 9 2 4 6 8 1)
with signature (1 4 7 1) (2 5 8 2) (3 6 9 3)
with signature (1 5 9 4 8 3 7 2 6 1)

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A ten-pointed star, called a decagram, has three configurations. The first-order star is composite,
being composed of two interlaced pentagons. The second-order star is prime. The third-order
decagram is composite. All previous composites have been composed of two or more polygons.
This is the first instance when the composite star is composed of two interlaced pentagrams.
When “n” is equal to ten, there are five even and five odd points, enabling us to have two
interlaced pentagrams.
Figure 15 - Decagram *10^1,
with signature (1 3 5 7 9 1) (2 4 6 8 10 2)
with signature (1 4 7 10 3 6 9 2 5 8 1)
with signature (1 5 9 3 7 1) (2 6 10 4 8 2)

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The eleven-pointed star, called hendecagram has four all prime configurations.
Figure 18 - Hendecagram *11^1,
with signature (1 3 5 7 9 11 2 4 6 8 10 1)
with signature (1 4 7 10 2 5 8 11 3 6 9 1)
with signature (1 5 9 2 6 10 3 7 11 4 8 1)
with signature (1 6 11 5 10 4 9 3 8 2 7 1)

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The twelve-pointed star, called dodecagram, also has four configurations, where only the fourth-
order star is prime. The first-order star is composed of two interlaced hexagons, the second-order
star is composed of three interlaced squares, and the third-order star has four interlaced
equilateral triangles as their compositions.
Figure 22 - Dodecagram *12^1,
with signature
(1 3 5 7 9 11 1) (2 4 6 8 10 12 2)
with signature
(1 4 7 10 1) (2 5 8 11 2) (3 6 9 12 3)
with signature
(1 5 9 1) (2 6 10 2) (3 7 11 3) (4 8 12 4)
with signature
(1 6 11 4 9 2 7 12 5 10 3 8 1)

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The thirteen-pointed star, called tridecagram has five all prime configurations.
Figure 26 - Tridecagram *13^1,
with signature (1 3 5 7 9 11 13 2 4 6 8 10 12 1)
with signature (1 4 7 10 13 3 6 9 12 2 5 8 11 1)
with signature
(1 5 9 13 4 8 12 3 7 11 2 6 10 1)
with signature
(1 6 11 3 8 13 5 10 2 7 12 4 9 1)

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with signature
(1 7 13 6 12 5 11 4 10 3 9 2 8 1)
A fourteen-pointed star is called a tetradecagram. It has five configurations. The second and
fourth order stars are prime. The first order star is composed of two interlaced septagons. The
third and fifth order stars are composed of two interlaced septagrams: septagrams of the first
order in one and septagrams of the second order in the other.
Figure 31 - Tetradecagram *14^1,
with signature
(1 3 5 7 9 11 13 1) (2 4 6 8 10 12 14 2)
with signature
(1 4 7 10 13 2 5 8 11 14 3 6 9 12 1)

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with signature
(1 5 9 13 3 7 11 1) (2 6 10 14 4 8 12 2)
with signature
(1 6 11 2 7 12 3 8 13 4 9 14 5 10 1)
with signature
(1 7 13 5 11 3 9 1) (2 8 14 6 12 4 10 2)

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TABLE OF POLYGRAM SIGNATURES
Points “n” Order “m” Type Signature
5 1 Prime (1 3 5 2 4 1)
6 1 Composite (1 3 5 1) (2 4 6 2)
7 1 Prime (1 3 5 7 2 4 6 1)
7 2 Prime (1 4 7 3 6 2 5 1)
8 1 Composite (1 3 5 7 1) (2 4 6 8 2)
8 2 Prime (1 4 7 2 5 8 3 6 1)
9 1 Prime (1 3 5 7 9 2 4 6 8 1)
9 2 Composite (1 4 7 1) (2 5 8 2) (3 6 9 3)
9 3 Prime (1 5 9 4 8 3 7 2 6 1)
10 1 Composite (1 3 5 7 9 1) (2 4 6 8 10 2)
10 2 Prime (1 4 7 10 3 6 9 2 5 8 1)
10 3 Composite (1 5 9 3 7 1) (2 6 10 4 8 2)
11 1 Prime (1 3 5 7 9 11 2 4 6 8 10 1)
11 2 Prime (1 4 7 10 2 5 8 11 3 6 9 1)
11 3 Prime (1 5 9 2 6 10 3 7 11 4 8 1)
11 4 Prime (1 6 11 5 10 4 9 3 8 2 7 1)
12 1 Composite (1 3 5 7 9 11 1) (2 4 6 8 10 12 2)
12 2 Composite (1 4 7 10 1) (2 5 8 11 2) (3 6 9 12 3)
12 3 Composite (1 5 9 1) (2 6 10 2) (3 7 11 3) (4 8 12 4)
12 4 Prime (1 6 11 4 9 2 7 12 5 10 3 8 1)
13 1 Prime (1 3 5 7 9 11 13 2 4 6 8 10 12 1)
13 2 Prime (1 4 7 10 13 3 6 9 12 2 5 8 11 1)
13 3 Prime (1 5 9 13 4 8 12 3 7 11 2 6 10 1)
13 4 Prime (1 6 11 3 8 13 5 10 2 7 12 4 9 1)
13 5 Prime (1 7 13 6 12 5 11 4 10 3 9 2 8 1)
14 1 Composite (1 3 5 7 9 11 13 1) (2 4 6 8 10 12 14 2)
14 2 Prime (1 4 7 10 13 2 5 8 11 14 3 6 9 12 1)
14 3 Composite (1 5 9 13 3 7 11 1) (2 6 10 14 4 8 12 2)
14 4 Prime (1 6 11 2 7 12 3 8 13 4 9 14 5 10 1)
14 5 Composite (1 7 13 5 11 3 9 1) (2 8 14 6 12 4 10 2)

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SOME OBSERVATIONS
These observations are given without any proofs. In most cases the proofs are self-evident, or
easily derived.
In this class of stars, the first thing to notice is that at the core of each polygram is a polygon
having the same number of sides as the polygram has points.
The minimum number of points a polygram can have is five which gives us a pentagram. In other
words, the smallest value for “n” can be five.
For a given “n” there is a limit to the maximum value of “m”, that is, the highest order the
polygram can have. This value is also the number of configurations the star can have. We will
designate “M” to be the highest value “m” can have for a given “n”.
The value of “M” is given by the equation M = (n - 3)/ 2 after discarding any fractional part. If “n”
is a prime number, then all of the “M” configurations of the star are prime polygrams. If “n” is not a
prime number, then the prime factors of “n” will determine which of the “M” configurations are
prime, and which are composite. Further, the prime factors of “n” will also determine the
compositions of the composite polygrams.
A BRIEF INTRODUCTION TO HYBRID POLYGRAMS
Consider the two fourteen-pointed stars *14^3 and *14^5. Both these stars are composite stars
composed of two septagrams. Whereas *14^3 is composed of two septagrams of the first order,
the other star *14^5 is composed of two septagrams of the second order. But in both these stars,
all the odd numbered points form one septagram, and all the even numbered points form the
second septagram, which interlace each other.
Notice that the prime factors of 14 are 2 and 7 and for “n” equal to seven, “M” is equal to two.
Consider now, this new, and different fourteen-pointed star. Inscribe a septagram of the first
order using all the odd numbered points and interlace it with another septagram of the second
order inscribed in all the even numbered joints. Its signature is (1 5 9 13 3 7 11 1) (2 8 14 6 12 4
10 2).

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Figure 36 - Hybrid Tetradecagram,
with signature
(1 5 9 13 3 7 11 1) (2 8 14 6 12 4 10 2)
This is of a different class of stars. It is not regular, as all sides and all angles are not equal. The
central core is not a fourteen-sided polygon, even though the star is a fourteen-pointed polygram.
And yet, it is composed of two regular septagrams. This class of stars may be classified as “hybrid
polygrams”.
Probably the best way to represent this hybrid tetradecagram is *(2x7)^(1, 2) indicating that
there are two seven-pointed stars of the first and second orders. Or, in a more generalized form,
*(k x n)^(m1 ,m2, m3, …, mk), indicating that there are “k” number of “m”-pointed stars of the
several orders m1 ,m2, m3, …, mk.
We shall dwell bit more on this before calling it a day.
The next prime number after seven is eleven, and an eleven-pointed star (hendecagram) has four
prime configurations. So, we can have numerous stars with:
 2 x 11 = 22 points, composed of any two hendecagrams of different permissible orders, or
 3 x 11 = 33 points, composed of any three hendecagrams of different permissible orders,
or
 4 x 11 = 44 points, composed of the four hendecagrams of different permissible orders
And then to the next prime, and the next … and the next, ad infinitum.

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But that's not all folks. There are many more classes of stars than the two essayed here. So, as
Perry Como sings, “don't let the stars get in your eyes”.
Except as otherwise expressly permitted under copyright law, no copying, redistribution, retransmission,
publication or commercial exploitation of this material will be permitted without the express permission of the
copyright owner. In the event of any permitted copying, redistribution or publication of copyright material, no
changes in or deletion of author attribution, trademark legend or copyright notice shall be made. You
acknowledge that you do not acquire any ownership rights by downloading this copyrighted material.

The Geometry of Stars

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