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37. The Regular Heptadecagon
To construct a regular heptadecagon, i.e., a regular 17-gon.
This celebrated problem was solved by Gauss in his major work Disquisitiones
arithmeticae, published in 1801. In the section dealing with solutions to x n 1, Gauss
proved the following
Theorem A regular n-gon can be constructed with compass and straightedge if and only
if n 2 m p 1 p 2 . . . p v , where p 1 , p 2, . . . , p v are distinct prime numbers of the form 2 k 1.
For m 0, v 1 and p 1 3 and p 1 5 we get the cases of the equilateral triangle and
pentagon respectively, which had already been solved in antiquity. [m 0, v 2, p 1 3 and
p 2 5 gives the case of the regular 15-gon, also found in Euclid.] Gauss said "The division
of a circle into three and into five equal parts was already known in Euclid’s time; it is
amazing that nothing new was added to these discoveries in the next two thousand years,
that geometers (mathematicians) considered it as settled that, except for these cases and
those that could be derived from them, regular polygons could not be constructed with
compass and straightedge."
Gauss’ advances were possible because he transformed the originally purely
geometrical problem into an algebraic one. He arrived at this transformation in the course
of representing complex numbers in the plane. An arbitrary complex number z a bi is
usually represented the point a, b in the plane; this point (or the vector from O to a, b )
itself is call "the complex number z. " Another common representation is the trigonometric
form
Ÿ
Ÿ
z r cos 2 i sin 2
Ÿ
where r |z| is the magnitude or modulus of z, its distance from the origin O, and 2 is the
angle or argument of z, 2 being measured from the positive real axis to z (thought of as a
vector.)
iY
z= a+bi= (a,b)
r
θ
O = (0,0)
rsin θ
X
rcos θ
The points on the unit circle |z| 1 are of the form
e iI cos I i sin I.
1
Ÿ
e iI
n
e iŸnI or
cos I i sin I
Ÿ
n
cos nI i sin nI,
which is known as Demoivre’s formula (Abraham Demoivre, 1667-1754).
To obtain a regular polygon of n sides we mark off the angle I succession from 1 on the unit circle. The resulting points
2=
n
n times in
/ 1 / cos I i sin I
/2
cos 2I i sin 2I
B
/n
cos nI i sin nI 1
/ v / v1 / v and / nv / vn Ÿ/ n v Ÿcos 2= i sin 2= v 1, and the n points / 1 , / 2 , . . . , / n of a
regular n-gon are therefore roots of the equation z n 1. Thus the geometric problem of
"constructing a regular n-gon" by Gauss, is equivalent to the problem "of finding
(constructing) the roots of the equation z n 1. "
The roots of z n 1, aside from z 1, satisfy the equation
z n " 1 z n"1 z n"2 . . . z 2 z 1 0,
z"1
th
the n cyclotomic polynomial. (Dörrie continues with a discussion of how to prove Gauss’
Theorem above, without going into all the details. For the sequel, note that the sum of the
roots is "1. He then applies this method to the regular 17-gon.)
We will now use Gauss’ method to solve the equation, i.e., construct the roots of
z 16 z 15 . . . z 2 z 1 0.
Let I 217= , / / 1 cos I i sin I, / v / v , and accordingly / 1 , / 2 , . . . , / 17 are the vertices of
the 17-gon.
2
ε4
ε5
ε6
ε3
ε2
ε7
2π i
ε1 = 17
ε8
ε0 =1
O
ε9
ε16
ε10
ε15
ε11
ε12
ε13
ε14
Let g 3. g is a primitive root mod 17, i.e., g 16 q 1 mod 17, but now smaller positive power
of g has this property. Thus mod 17, the powers of g, i.e., g, g 2 , g 3 , . . . , g 16 are 1, 2, 3, . . . , 16 in
some order (3, 9, 10, . . . , 1), and the roots of the cyclotomic polynomial above are
v
v1
v
z v / g , v 1, 2, . . . , 16. Since z v1 / g / g g z gv , each root in the sequence
z 0 , z 1 , z 2 , . . . , z 15 is the cube of the preceding one. (Remember g 3. )
z 0 /,
z1 /3,
z2 /9,
z 3 / 10 ,
z 4 / 13 , z 5 / 5 ,
z 6 / 15 , z 7 / 11 ,
z 8 / 16 , z 9 / 14 ,
z 10 / 8 , z 11 / 7 ,
z 12 / 4 , z 13 / 12 , z 14 / 2 , z 15 / 6 .
Let
X z 0 z 2 z 4 z 6 z 8 z 10 z 12 z 14
/ / 9 / 13 / 15 / 16 / 8 / 4 / 2
x z 1 z 3 z 5 z 7 z 9 z 11 z 13 z 15
and
/ 3 / 10 / 5 / 11 / 14 / 7 / 12 / 6 .
(g 3 enters the picture in determining the z i s, and the /s above: each is the 9 th g 2
power of the preceding term.) The sum of the roots of the cyclotomic polynomial is "1, so
X x "1. It is somewhat tedious, but easy to check that Xx equals four times the sum of
the roots, so Xx "4. Thus X and x satisfy the quadratic equation
Ÿ
th
3
t2 t " 4 0
(I)
and
X
"1 17
and x 2
"1 " 17
.
2
To see that X x, we note that Re / 6 Re / v if 6 v 17. (See the unit circle above; / 6 and
/ v are conjugates in this case.) From this we obtain
Re X 2 Re / 1 Re / 2 Re / 4 Re / 8
Ÿ
Re x
2 Re / 3 Re / 5 Re / 6 Re / 7
Ÿ
0
0.
Next let
U z 0 z 4 z 8 z 12
z 2 z 6 z 10 z 14
V z 1 z 5 z 9 z 13
v z 3 z 7 z 11 z 15
u
/ / 13 / 16 / 4
/ 9 / 15 / 8 / 2
/ 3 / 5 / 14 / 12
/ 10 / 11 / 7 / 6
(g 3 enters the picture in determining the z i s, and the /s above: each is the 81 st g 4
power of the preceding term, and U u X. ) Here we obtain
Ÿ
th
U u X, V v x
Uu "1,
Vv "1,
roots of the quadratic equations
t 2 " Xt " 1 0
(II)
t 2 " xt " 1 0
and
respectively. It follows that
U
u
X X 2 4
2
X" X 2 4
2
, V
x x 2 4
2
,
v
x x 2 4
2
,
,
where we conclude that U u and V v from
Re U 2 Re / 1 Re / 4 , Re V 2 Re / 3 Re / 5 ,
Ÿ
Re u 2 Re / 2 Re / 8 ,
Ÿ
Ÿ
Re v 2 Re / 6 Re / 7 .
Ÿ
Finally let
4
W z0 z8
w
z 4 z 12
/ / 16
/ 13 / 4 .
(g 3 enters the picture in determining the z i s, and the /s above: each is the 6561 st g 8
power of the preceding term.) In this case, W w U and Ww / 5 / 14 / 3 / 12 V.
Since Re W 2 Re / 1 and Re w 2 Re / 4 , W w. W and w are thus roots of the quadratic
equation
Ÿ
(III)
th
t 2 " Ut V 0.
The construction of the regular 17-gon then consists of the following four steps:
1.
2.
3.
4.
Construct X and x;
construct U and V (from X and x);
construct W and w (from U and V) according to (III);
find W on the real axis; the perpendicular bisector of the segment OW cuts the unit
circle in points / 1 and / 16 . All the other vertices are now determined.
Note 1. Gauss was so proud of this discovery that he wanted a regular 17-gon inscribed
on his tombstone. This wish was not carried out.
Note 2. Most geometry software programs include rotation tools that enable the user to
easily draw regular n-gons.
Note 3. Primes of the form 2 k 1 are called Fermat primes. The only ones known today
(2010) are 3, 5, 17, 257 and 65537.
5