AoPS Academy
![$a,b,c\in{[2-\sqrt{3},2+\sqrt{3}]},$](http://latex.artofproblemsolving.com/0/c/9/0c9d55a20ca1a60e4d0cd51e44171923fc44abf1.png)
then ![\[2(\frac{a}{b}+\frac{b}{c}+\frac{c}{a})\geq \frac{b}{a}+\frac{c}{b}+\frac{a}{c}+3\]](http://latex.artofproblemsolving.com/4/c/0/4c092e0e8e46d1014b2cc80caee0f5959003c36f.png)
![$a,b,c,d\in{[\frac{1}{2},2]},$](http://latex.artofproblemsolving.com/b/6/9/b69e17212ca1f383bf3f1abf908169d012a8e12b.png)
then ![\[2(\frac{a}{b}+\frac{b}{c}+\frac{c}{d}+\frac{d}{a})\geq \frac{b}{a}+\frac{c}{b}+\frac{d}{c}+\frac{a}{d}+4\]](http://latex.artofproblemsolving.com/9/6/c/96cc857aeceb419f95f7fea36fcd44428fe26d55.png)
+1 w
be an acute scalene triangle with circumcenter 
. Let 
be the feet of the altitudes from 
to 
respectively. Let 
be the midpoint of 
. Let 
be the circle with diameter 
. Let 
be the intersection of 
and 
. Let 
be the orthocenter of . Let 
be the intersection of 
and . Let 
be the lines through 
tangent to 
respectively. Let 
be the intersection of 
and 
. Let 
be the intersection of 
and 
. Let 
be the line through parallel to 
and let 
be the reflection of across . Prove that 
is tangent to 
.
, where 
it is positiv ,integer number.
be a polynomial with integer coefficients. Suppose there exist infinitely many integer pairs 
such that 
. Prove that the graph of is symmetric about a point (i.e., it has a center of symmetry).
on the Cartesian coordinate plane. If it has a center of symmetry, we can translate the graph so the center moves to the origin 
, and the resulting function becomes an odd function. This means the graph of is symmetric about a point 
if and only if the translated function 
is an odd function, i.e., 
holds for some fixed 
and for all 
.
Thus, we can fix some integers 
with 
such that 
, and the function increases on 
and decreases on 
. Without loss of generality (WLOG), assume 
. Let 
. Since 
and 
, we have 
, so 
.
for all sufficiently large 
. is equivalent to ![$$[n(a+t)+1]m^{n-1}+\text{lower order terms in } m > [-nb+1]m^{n-1} +\text{lower order terms in} \;m.$$](http://latex.artofproblemsolving.com/7/e/e/7ee2bef564707b8110376687e64b12c4de04e5fb.png)
This is always true for sufficiently large . 
such that 
. From the claim, we must have 
, or 
. Similarly, one can argue that 
. This means that for these infinitely many pairs , the integer difference 
must lie in the finite interval ![$[-t, t]$](http://latex.artofproblemsolving.com/9/f/3/9f3ede48f04a41c215ea59717c0b04ec9fbcbb9f.png)
. By the Pigeonhole Principle (PHP), since there are infinitely many such pairs but only a finite number of integer values in , there must be infinitely many pairs satisfying the condition for which 
for some fixed integer ![$q \in [-t, t]$](http://latex.artofproblemsolving.com/9/c/3/9c3d398bda3c1905847d524b615d20c9a73aa825.png)
.
such that
By the identity theorem for polynomials, this implies the polynomial identity:
Let 
. Replacing with 
in the identity gives:
This equation signifies that the function 
is an odd function (
), which means the graph of the original polynomial has a center of symmetry.
, such that for all 
:![\[ f(x+f(y))=\dfrac{f(x)}{1+f(xy)}\]](http://latex.artofproblemsolving.com/1/4/1/1418fad9fd00b31c38bfbc5657e2a322d66ef450.png)
![\[\mathcal{P}(x) = x^{108}+x^{102}+x^{96}+2x^{54}+3x^{36}+4x^{24}+5x^{18}+6\]](http://latex.artofproblemsolving.com/e/b/2/eb28918359848dd07784a3c2c6a34b934743c016.png)
be 
.![\[\dfrac{r_1^6+r_2^6+\dots+r_{108}^6}{r_1^6r_2^6+r_1^6r_3^6+\dots+r_{107}^6r_{108}^6}\]](http://latex.artofproblemsolving.com/3/1/5/315341a7adf35bc04e40ee0685a011c9f7b76115.png)
without Newton Sums.
