Respuesta :
First of all, let me break down the formula: [tex] x^2-y^2,\ 2xy,\ x^2+y^2 [/tex] is always a Pythagorean triple because you have
[tex] (x^2-y^2)^2+(2xy)^2 = x^4-2x^2y^2+y^4+4x^2y^2 = x^4+2x^2y^2+y^4 = (x^2+y^2)^2 [/tex]
So, for any [tex] x,y>0 [/tex] you can choose (let's suppose [tex] x>y [/tex]), these three numbers will always fall in the form [tex] a^2+b^2=c^2 [/tex], which is also the rule that works for right triangles. So, every time you choose two numbers [tex] x,y>0 [/tex], the legs will be [tex] x^2-y^2[/tex] and [tex] 2xy[/tex], while the hypotenuse will be [tex]x^2+y^2 [/tex].
We have to find a right triangles with legs 16 and an odd number. Well, the legs in the triple we are given are [tex] x^2-y^2[/tex] and [tex] 2xy[/tex], so we want one of this to be 16, and the other to be odd. But [tex] 2xy[/tex] can't be odd, because it has a 2 factor in it. So, it must be 16: we have
[tex] 2xy=16 \iff xy=8 [/tex]
The only ways we can choose two numbers [tex] x>y>0 [/tex] such that their product is 8 are:
[tex] x=8,\ y=1,\quad x=4,\ y=2 [/tex]
In the first case, the legs are
[tex] x^2-y^2 = 64-1 = 63,\ 2xy = 16 [/tex]
In the second case, the legs are
[tex] x^2-y^2 = 16-4 = 12,\ 2xy = 16 [/tex]
In this case both legs are even, so the only good choice is [tex] x=8,\ y=1[/tex]
So, the triangle we're working with has legs
[tex] x^2-y^2 = 64-1 = 63,\ 2xy = 16 [/tex]
and hypotenuse
[tex] x^2+y^2 = 64+1 = 65 [/tex]
