Advanced book on Mathematics Olympiad

680 Number Theory

x 0 =m^2 +n^2 ,x 0 +y 0 − 2 z 0 =p^2 +q^2 ,z 0 −x 0 =mp+nq.

In that case,

y 0 =p^2 +q^2 + 2 z 0 −x 0 =p^2 +q^2 + 2 mp+ 2 nq+m^2 +n^2 =(m+p)^2 +(n+q)^2

and

z 0 =m(m+p)+n(n+q),

contradicting our assumption.
We therefore can construct inductively an infinite sequence of triples of positive
numbers(xn,yn,zn),n≥0, none of which admits the representation from the statement,
and such thatxn+yn+zn>xn+ 1 +yn+ 1 +zn+ 1 for alln. This is of course impossible,
and the claim is proved.
(short list of the 20th International Mathematical Olympiad, 1978)

714.First solution: Chooseksuch that

x+

k

n

≤x<x+

k+ 1

n

.

Thenx+jnis equal toxforj = 0 , 1 ,...,n−k−1, and tox+1 forx =
n−k,...,n−1. It follows that the expression on the left is equal tonx+k. Also,
nx=nx+k, which shows that the two sides of the identity are indeed equal.

Second solution: Definef:R→N,

f(x)=x+

⌊

x+

1

n

⌋

+···+

⌊

x+

n− 1

n

⌋

−nx.

We have

f

(

x+

1

n

)

=

⌊

x+

1

n

⌋

+···+

⌊

x+

n− 1

n

⌋

+

⌊

x+

n

n

⌋

−nx+ 1 =f(x).

Therefore,fis periodic, with period^1 n. Also, sincef(x)=0 forx∈[ 0 ,^1 n), it follows
thatfis identically 0, and the identity is proved.
(Ch. Hermite)

715.Denote the sum in question bySn. Observe that

Sn−Sn− 1 =

⌊x

n

⌋

+

⌊

x+ 1

n

⌋

+···+

⌊

x+n− 1

n

⌋

=

⌊x

n

⌋

+

⌊

x

n

+

1

n

⌋

+···+

⌊

x

n

+

n− 1

n

⌋

,