Found problems: 85335
1987 Greece National Olympiad, 2
If for function $f$ holds that $$f(x)+f(x+1)+f(x+2)+...+f(x+1986)=0$$ for any $\in\mathbb{R}$, prove that $f$ is periodic and find one period of her.
2012 Princeton University Math Competition, A8
Cyclic quadrilateral $ABCD$ has side lengths $AB = 2, BC = 3, CD = 5, AD = 4$.
Find $\sin A \sin B(\cot A/2 + \cot B/2 + \cot C/2 + \cot D/2)^2$.
Your answer can be written in simplest form as $a/b$. Find $a + b$.
Kvant 2021, M2636
We call a natural number $p{}$ [i]simple[/i] if for any natural number $k{}$ such that $2\leqslant k\leqslant \sqrt{p}$ the inequality $\{p/k\}\geqslant 0,01$ holds. Is the set of simple prime numbers finite?
[i]Proposed by M. Didin[/i]
2019 Costa Rica - Final Round, G2
Let $H$ be the orthocenter and $O$ the circumcenter of the acute triangle $\vartriangle ABC$. The circle with center $H$ and radius $HA$ intersects the lines $AC$ and $AB$ at points $P$ and $Q$, respectively. Let point $O$ be the orthocenter of triangle $\vartriangle APQ$, determine the measure of $\angle BAC$.
2010 Saudi Arabia IMO TST, 3
Find all primes $p$ for which $p^2 - p + 1$ is a perfect cube.
2014 Spain Mathematical Olympiad, 1
Is it possible to place the numbers $0,1,2,\dots,9$ on a circle so that the sum of any three consecutive numbers is a) 13, b) 14, c) 15?
2019 LIMIT Category B, Problem 9
Let $f:\mathbb R\to\mathbb R$ be given by
$$f(x)=\left|x^2-1\right|,x\in\mathbb R$$Then
$\textbf{(A)}~f\text{ has local minima at }x=\pm1\text{ but no local maxima}$
$\textbf{(B)}~f\text{ has a local maximum at }x=0\text{ but no local minima}$
$\textbf{(C)}~f\text{ has local minima at }x=\pm1\text{ and a local maximum at }x=0$
$\textbf{(D)}~\text{None of the above}$
2005 Flanders Junior Olympiad, 2
Starting with two points A and B, some circles and points are constructed as shown in
the figure:[list][*]the circle with centre A through B
[*]the circle with centre B through A
[*]the circle with centre C through A
[*]the circle with centre D through B
[*]the circle with centre E through A
[*]the circle with centre F through A
[*]the circle with centre G through A[/list]
[i][size=75](I think the wording is not very rigorous, you should assume intersections from the drawing)[/size][/i]
Show that $M$ is the midpoint of $AB$.
[img]https://cdn.artofproblemsolving.com/attachments/d/4/2352ab21cc19549f0381e88ddde9dce4299c2e.png[/img]
1996 IMC, 5
i) Let $a,b$ be real numbers such that $b\leq 0$ and $1+ax+bx^{2} \geq 0$ for every $x\in [0,1]$.
Prove that
$$\lim_{n\to \infty} n \int_{0}^{1}(1+ax+bx^{2})^{n}dx= \begin{cases}
-\frac{1}{a} &\text{if}\; a<0,\\
\infty & \text{if}\; a \geq 0.
\end{cases}$$
ii) Let $f:[0,1]\rightarrow[0,\infty)$ be a function with a continuous second derivative and let $f''(x)\leq0$ for every $x\in [0,1]$. Suppose that $L=\lim_{n\to \infty} n \int_{0}^{1}(f(x))^{n}dx$ exists and $0<L<\infty$. Prove that $f'$ has a constant sign and $\min_{x\in [0,1]}|f'(x)|=L^{-1}$.
2017 Harvard-MIT Mathematics Tournament, 10
Let $LBC$ be a fixed triangle with $LB = LC$, and let $A$ be a variable point on arc $LB$ of its circumcircle. Let $I$ be the incenter of $\triangle ABC$ and $\overline{AK}$ the altitude from $A$. The circumcircle of $\triangle IKL$ intersects lines $KA$ and $BC$ again at $U \neq K$ and $V \neq K$. Finally, let $T$ be the projection of $I$ onto line $UV$. Prove that the line through $T$ and the midpoint of $\overline{IK}$ passes through a fixed point as $A$ varies.
2011 India IMO Training Camp, 2
Find all pairs $(m,n)$ of nonnegative integers for which \[m^2 + 2 \cdot 3^n = m\left(2^{n+1} - 1\right).\]
[i]Proposed by Angelo Di Pasquale, Australia[/i]
2013 Balkan MO Shortlist, N9
Let $n\ge 2$ be a given integer. Determine all sequences $x_1,...,x_n$ of positive rational numbers such that
$x_1^{x_2}=x_2^{x_3}=...=x_{n-1}^{x_n}=x_n^{x_1}$
2007 Stars of Mathematics, 3
Let $ ABC $ be a triangle and $ A_1,B_1,C_1 $ the projections of $ A,B,C $ on their opposite sides. Let $ A_2,A_3 $ be the projection of $ A_1 $ on $ AB, $ respectively on $ AC. B_2,B_3,C_2,C_3 $ are defined analogously. Moreover, $ A_4 $ is the intersection of $ B_2B_3 $ with $ C_2C_3; B_4, $ the intersection of $C_2C_3 $ with $ A_2A_3; C_4, $ the intersection of $ A_2A_3 $ with $ B_2B_3. $
Show that $ AA_4,BB_4 $ and $ CC_4 $ are concurrent.
1996 Czech And Slovak Olympiad IIIA, 4
Points $A$ and $B$ on the rays $CX$ and $CY$ respectively of an acute angle $XCY$ are given so that $CX < CA = CB < CY$. Construct a line meeting the ray $CX$ and the segments $AB,BC$ at $K,L,M$, respectively, such that $KA \cdot YB = XA \cdot MB = LA\cdot LB \ne 0$.
2021 BMT, 9
Let $ABCD$ be a convex quadrilateral such that $\vartriangle ABC$ is equilateral. Let $P$ be a point inside the quadrilateral such that $\vartriangle AP D$ is equilateral and $\angle P CD = 30^o$ . Given that $CP = 2$ and $CD = 3$, compute the area of the triangle formed by $P$, the midpoint of segment $\overline{BC}$, and the midpoint of segment $\overline{AB}$.
2000 IMO Shortlist, 8
Let $ AH_1, BH_2, CH_3$ be the altitudes of an acute angled triangle $ ABC$. Its incircle touches the sides $ BC, AC$ and $ AB$ at $ T_1, T_2$ and $ T_3$ respectively. Consider the symmetric images of the lines $ H_1H_2, H_2H_3$ and $ H_3H_1$ with respect to the lines $ T_1T_2, T_2T_3$ and $ T_3T_1$. Prove that these images form a triangle whose vertices lie on the incircle of $ ABC$.
1949-56 Chisinau City MO, 60
Show that the sum of the distances from any point of a regular tetrahedron to its faces is equal to the height of this tetrahedron.
2015 Germany Team Selection Test, 3
Let $ABC$ be an acute triangle with $|AB| \neq |AC|$ and the midpoints of segments $[AB]$ and $[AC]$ be $D$ resp. $E$. The circumcircles of the triangles $BCD$ and $BCE$ intersect the circumcircle of triangle $ADE$ in $P$ resp. $Q$ with $P \neq D$ and $Q \neq E$.
Prove $|AP|=|AQ|$.
[i](Notation: $|\cdot|$ denotes the length of a segment and $[\cdot]$ denotes the line segment.)[/i]
1976 IMO Longlists, 25
We consider the following system
with $q=2p$:
\[\begin{matrix} a_{11}x_{1}+\ldots+a_{1q}x_{q}=0,\\ a_{21}x_{1}+\ldots+a_{2q}x_{q}=0,\\ \ldots ,\\ a_{p1}x_{1}+\ldots+a_{pq}x_{q}=0,\\ \end{matrix}\]
in which every coefficient is an element from the set $\{-1,0,1\}$$.$ Prove that there exists a solution $x_{1}, \ldots,x_{q}$ for the system with the properties:
[b]a.)[/b] all $x_{j}, j=1,\ldots,q$ are integers$;$
[b]b.)[/b] there exists at least one j for which $x_{j} \neq 0;$
[b]c.)[/b] $|x_{j}| \leq q$ for any $j=1, \ldots ,q.$
2019 Oral Moscow Geometry Olympiad, 3
In the acute triangle $ABC, \angle ABC = 60^o , O$ is the center of the circumscribed circle and $H$ is the orthocenter. The angle bisector $BL$ intersects the circumscribed circle at the point $W, X$ is the intersection point of segments $WH$ and $AC$ . Prove that points $O, L, X$ and $H$ lie on the same circle.
1998 Estonia National Olympiad, 1
Solve the equation $x^2+1 = log_2(x+2)- 2x$.
V Soros Olympiad 1998 - 99 (Russia), 9.10
The bisector of angle $\angle BAC$ of triangle $ABC$ intersects arc $BC$ (not containing point $A$) of the circle circumscribed around this triangle at point $P$. Segment $AP$ is divided by side $BC$ in ratio $k$ (counting from vertex $A$). Find the perimeter of triangle $ABC$ if $BC = a$.
1974 IMO Longlists, 44
We are given $n$ mass points of equal mass in space. We define a sequence of points $O_1,O_2,O_3,\ldots $ as follows: $O_1$ is an arbitrary point (within the unit distance of at least one of the $n$ points); $O_2$ is the centre of gravity of all the $n$ given points that are inside the unit sphere centred at $O_1$;$O_3$ is the centre of gravity of all of the $n$ given points that are inside the unit sphere centred at $O_2$; etc. Prove that starting from some $m$, all points $O_m,O_{m+1},O_{m+2},\ldots$ coincide.
2021 Baltic Way, 1
Let $n$ be a positive integer. Find all functions $f\colon \mathbb{R}\rightarrow \mathbb{R}$ that satisfy the equation
$$
(f(x))^n f(x+y) = (f(x))^{n+1} + x^n f(y)
$$
for all $x ,y \in \mathbb{R}$.
2009 India National Olympiad, 5
Let $ ABC$ be an acute angled triangle and let $ H$ be its ortho centre. Let $ h_{max}$ denote the largest altitude of the triangle $ ABC$. Prove that:
$AH \plus{} BH \plus{} CH\leq2h_{max}$