Abstract:
In a short survey of survey of primitive Pythagorean triples (x,y,z) 0 < x < y < z
, we have found that one of x, y, z is divisible by 5 and z is not divisible by 3, there
are Pythagorean triples whose corresponding element are equal , but there cannot be two
Pythagorean triples such that (x10 y��" z1 ), (x1, zP z
2
) , where z1 and z
2
hypotenuses of the
corresponding Pythagorean triples. This is due to a Fermat's theorem [1] that the area of a
Pythagorean triangle cannot be a perfect square of an integer, which can directly be used
to prove Fermat's last theorem for n = 4. Therefore the preceding theorem is proved using
elementary mathematics, which is the one of the main objectives of this contribution. All
results in this contribution are summarized as a theorem.
Theorem
If (x, y, z) is a primitive Pythagorean triangle, where z is the hypotenuse, then z is never
divisible by 3, andJ? = O(mod3) , xyz = O(mod5) ,and there are Pythagorean triangles
whose corresponding one side is the same. But there are no two Pythagorean triangles such
that (x1,y"z1) , (x"z"z
2
) ), where z"z
2
are hypotenuses.
Proof of the theorem
Pythagoras' equation can be written as
z2 =y2+x2 ,(x,y)= 1 (1)
and if z = O(mod 3) ,then since J? is not divisible by 3, z2= y2 -1+ x2 -1+ 2 .Now,
it follows at once from Fermat's little theorem that z cannot be divisible by 3. If
xyz is not divisible by 5, squaring (1), one obtains z4 = y4 + x4 + 2x2 y2 and hence
z4 -1 = y4 -1+ x 4 -1+ 2(x2 y2 ± 1)+ t, where t =- 1 or 3. Therefore xyz = O(mod5). It
is easy to obtain two Pythagorean triples whose corresponding two elements are equal,
from the pair-wise disjoint sets which have recently been obtained in Ref.2. For example
3652 =3642 +2 2 3652 =3642 +2 2 3652 =3572 +�� 2 .Now, assume that there exists ' '
two primitive Pythagorean triples of the form
a
z = bz + cz
dz =az +cz
(1)
(2)
It is clear that a is odd and c = O(mod 3) .F rom these two equations, one obtains immediately
d2 - b2 = 2c2, d2 + b2 = 2a2, and therefore
d4 -b4 = 4c2a2 = w�� (3)
It has been proved by Fermat, after obtaining the representation of the primitive Pythagorean
triples as x = 2rs,y = r2 -s2 ,z = r2 + s2, where 0 < s < r and r,s are of opposite parity,
that (3) has no non trivial integral solution for d,b, w.To prove the same in an easy
manner consider the equation d2 + b2 = 2a2 in the form d2 -a2 = a2 -b2 and writing it
as ( d -a)( d + a) = (a -b)( a +b) use the technique used in Ref.3 to obtain the parametric
solution for d andb If d -a= a -b., then d + b = 2a , from we deduce db= a2 .This
never holds since (d,a)= 1 = ( b,a) by (1) and (2).1f (d -a)!!=( a -b) , where (u, v) =1 ,
V
then V ( d + a)-= (a +b) . From these two relations, one derives the simultaneous
u
equations
vd -ub = a( u -v)
ud+vb=a(u+v)
(4a)
(4b)
From ( 4a),( 4b ),it is easy to deduce the relations that we need to prove the theorem as
(v2 + u2 )d = [2uv + u2 -v2 ]a, (v2 + u2 )b = [2uv -(u2 -v2 )]a,
(v2 +u2)(d+b))=4uva, v2 +u2 =2a, assuming that uand v are odd.
Hence d -b=(u2 -v2),(d+b)=2uv. Therefore d2 -b2 =2(u2 -v2)uv=2c2 and
hence u, v are perfect squares and we can find two integers g,h such that.
g4 -h4 = w21 < w�� .Now, proof of the last part of the theorem follows from the method of
infinite descends of Fermat. Even if u and v are of opposite parity proof of the theorem
can be done in the same way.
To complete the proof of a Fermat's theorem that g4 -h4 = w�� is not satisfied by any
non-trivial integers, we write (g2 + h2 )(g2 -h2) = w�� , where g,h are of opposite parity,
to obtain g2 + h2 = x2, g2 -h2 = y2 and x4 -y4 = 4g2 h2 = z�� , where x and y are odd
and eo-prime. But, in the case of the main theorem, we have shown that this is not
satisfied by any non-trivial odd x, y and even z0 numbers . This completes the proof of the
Fermat's theorem we mentioned above.