such that 
![\[f(x)+f(\lfloor x\rfloor)f(\{x\})=x,\]](http://latex.artofproblemsolving.com/6/4/1/6411452c9f27ac7a8a25141927ed2f34e810e6dd.png)
and draw its graph. Find all 
for which the equation 
has solutions for any 
.
be a prime number, and 
be a sequence defined by 
and 
,
.
terms of the sequence is not prime.
in the plane of a square 
for which ![\[\max (PA, PC)=\frac1{\sqrt2}(PB+PD).\]](http://latex.artofproblemsolving.com/3/9/8/3984b1970837a85af0bac93fd711843630a1fd99.png)
,
is an even number, then the polynomial ![\[-1+\prod_{k=0}^{n-1} P\left(X^{p^k}\right)\]](http://latex.artofproblemsolving.com/5/d/f/5df80f885e63852e4f53a6145dafd18d63dc3526.png)
is divisible by 
.
Y by nguyendangkhoa17112003, Me.021, Adventure10, Mango247
The altitudes through the vertices 
of an acute-angled triangle 
meet the opposite sides at 
respectively. The line through 
parallel to 
meets the lines 
and 
at 
and 
respectively. The line meets 
at 
Prove that the circumcircle of the triangle 
passes through the midpoint of 
of an acute-angled triangle 
meet the opposite sides at 
respectively. The line through 
parallel to 
meets the lines 
and 
at 
and 
respectively. The line meets 
at 
Prove that the circumcircle of the triangle 
passes through the midpoint of 
be the midpoint of 
be the orthocenter of 
.
to meet the circumcircle of 
and let 
meet 
at 
.
,
is cyclic. This circle has center 
.
,
is cyclic, which means that 
.
is cyclic, so 
.
,
is cyclic, so 
.
,
is cyclic. Thus, 
,
is cyclic, so the circumcircle of 
passes through the midpoint of 
?
is the same as 
;
to get that 
and intersection of diagonals being 
.
intersect at 
and 
.
and 
be 
.
respectively and the midpoints of 
respectively. Now, 
and 
,
.
,
,
is cyclic. Since 
,
is cyclic, so 
is cyclic. Thus, 
,
.
.
,
,
,
,
,
is cyclic. Since 
,
is cyclic, so 
,
.
.
!
is cyclic and 
,
is also cyclic. Therefore 
is a harmonic division, so 
,
=> (A,D;F,Y)=(B,C;G,Y)=1. Hence PX is polar of Y => 
.
QED (I think it's known as Brokard's theorem)
and 
cut circle 
again at 
Notice that 
the 9-point circle 
and the circle with diameter 
Inversion with center 
takes 
and 
In other words, circle 
is taken to the line 
But 
and 
is on the polar of the intersection of the diagonals of the quadrilateral 
WRT 
passes through 
If 
then its inverse 
passes through the inverse 
of 
Let 
be the circumradius of 
Let 
WLOG assume 
)
so 
By sine rule on 
we get that 
where we have used the fact that the radius of the nine point circle is half the circumradius. Similarly we get 
By sine rule on 
and using the fact that 
(which follows from sine rule in 
)
Also, note that 
from which the result follows by PoP. This is equivalent to showing
then: 
,
,
lie on a circle
or 
is cyclic.
We will prove that 
is cyclic. It is sufficient to show that 
.
.
Note that:
Since 
and 
and we are done.
is a complete quadrilateral so:![\[(CB,DP)=-1
\implies PB.PC=PD.PM \]](http://latex.artofproblemsolving.com/d/c/5/dc591ddef969f8608000ceb8b2bb8809db2e6515.png)
![\[\implies MD.DP=BD.DC \qquad (1)\]](http://latex.artofproblemsolving.com/2/e/e/2eeab26fb7deb8b82c457a69b9f665d022a4e802.png)
on the other hand we know that 
so 
is cyclic then:![\[BD.DC=RD.DQ\qquad (2)\]](http://latex.artofproblemsolving.com/b/d/6/bd6f60fbbc49ec1dba78f12f16b74bb9547289da.png)
combining 
and 
gives the desired result.
is cyclic 
.
be the second intersection of 
and 
.
are collinear. Also if 
is the reflection of 
w.r.t. 
and 
are collinear. Since 
are collinear we have that 
are collinear. Thus 
.
is the reflection of 
,
.
.
lies on the radical axis of 
,
and 
,
is cyclic. Done.
is a cyclic quadrilateral.
,
is cyclic this implies that 
by PoP, thus we have that 
,
is cyclic.
concure at 
.
is cyclic.
and that 
concyclic. Let 
thus 
By sinus Law.
so 
Since 
with respect to 
Hence, letting 
we see 
Therefore, 
Since 
are inverse wrt circle with diameter 
we obtain 
,
are concyclic. So, 
Moreover, since 
Combining 
and the result follows. 
and since 
,
so the result follows from 
.
