Found problems: 25757
2008 Oral Moscow Geometry Olympiad, 1
A coordinate system was drawn on the board and points $A (1,2)$ and $B (3,1)$ were marked. The coordinate system was erased. Restore it by the two marked points.
2001 Tournament Of Towns, 4
Let $F_1$ be an arbitrary convex quadrilateral. For $k\ge2$, $F_k$ is obtained by cutting $F_{k-1}$ into two pieces along one of its diagonals, flipping one piece over, and the glueing them back together along the same diagonal. What is the maximum number of non-congruent quadrilaterals in the sequence $\{F_k\}$?
1999 South africa National Olympiad, 1
How many non-congruent triangles with integer sides and perimeter 1999 can be constructed?
2017 IFYM, Sozopol, 8
$k$ is the circumscribed circle of $\Delta ABC$. $M$ and $N$ are arbitrary points on sides $CA$ and $CB$, and $MN$ intersects $k$ in points $U$ and $V$. Prove that the middle points of $BM$,$AN$,$MN$, and $UV$ lie on one circle.
2018 Ramnicean Hope, 3
Prove that for any noncollinear points $ A,B,C $ and positive real numbers $ x,y, $ the following inequality is true.
$$ xAB^2- \frac{xy}{x+y}BC^2 +yCA^2\ge 0 $$
[i]Constantin Rusu[/i]
2016 CCA Math Bonanza, I2
Rectangle $ABCD$ has perimeter $178$ and area $1848$. What is the length of the diagonal of the rectangle?
[i]2016 CCA Math Bonanza Individual Round #2[/i]
2009 Sharygin Geometry Olympiad, 1
Let $a, b, c$ be the lengths of some triangle's sides, $p, r$ be the semiperimeter and the inradius of triangle. Prove an inequality $\sqrt{\frac{ab(p- c)}{p}} +\sqrt{\frac{ca(p- b)}{p}} +\sqrt{\frac{bc(p-a)}{p}} \ge 6r$
(D.Shvetsov)
2020 Tournament Of Towns, 3
Is it possible that two cross-sections of a tetrahedron by two different cutting planes are two squares, one with a side of length no greater than $1$ and another with a side of length at least $100$?
Mikhail Evdokimov
2002 Federal Math Competition of S&M, Problem 2
The (Fibonacci) sequence $f_n$ is defined by $f_1=f_2=1$ and $f_{n+2}=f_{n+1}+f_n$ for
$n\ge1$. Prove that the area of the triangle with the sides $\sqrt{f_{2n+1}},\sqrt{f_{2n+2}},$ and $\sqrt{f_{2n+3}}$ is equal to $\frac12$.
2008 German National Olympiad, 2
The triangle $ \triangle SFA$ has a right angle at $ F$. The points $ P$ and $ Q$ lie on the line $ SF$ such that the point $ P$ lies between $ S$ and $ F$ and the point $ F$ is the midpoint of the segment $ [PQ]$. The circle $ k_1$ is th incircle of the triangle $ \triangle SPA$. The circle $ k_2$ lies outside the triangle $ \triangle SQA$ and touches the segment $ [QA]$ and the lines $ SQ$ and $ SA$.
Prove that the sum of the radii of the circles $ k_1$ and $ k_2$ equals the length of $ [FA]$.
1988 Irish Math Olympiad, 1
A pyramid with a square base, and all its edges of length $2$, is joined to a regular tetrahedron, whose edges are also of length $2$, by gluing together two of the triangular faces. Find the sum of the lengths of the edges of the resulting solid.
2024 CMIMC Geometry, 3
Circles $C_1$, $C_2$, and $C_3$ are inside a rectangle $WXYZ$ such that $C_1$ is tangent to $\overline{WX}$, $\overline{ZW}$, and $\overline{YZ}$; $C_2$ is tangent to $\overline{WX}$ and $\overline{XY}$; and $C_3$ is tangent to $\overline{YZ}$, $C_1$, and $C_2$. If the radii of $C_1$, $C_2$, and $C_3$ are $1$, $\tfrac 12$, and $\tfrac 23$ respectively, compute the area of the triangle formed by the centers of $C_1$, $C_2$, and $C_3$.
[i]Proposed by Connor Gordon[/i]
1982 Miklós Schweitzer, 8
Show that for any natural number $ n$ and any real number $ d > 3^n / (3^n\minus{}1)$, one can find a covering of the unit square with $ n$ homothetic triangles with area of the union less than $ d$.
2008 USA Team Selection Test, 9
Let $ n$ be a positive integer. Given an integer coefficient polynomial $ f(x)$, define its [i]signature modulo $ n$[/i] to be the (ordered) sequence $ f(1), \ldots , f(n)$ modulo $ n$. Of the $ n^n$ such $ n$-term sequences of integers modulo $ n$, how many are the signature of some polynomial $ f(x)$ if
a) $ n$ is a positive integer not divisible by the square of a prime.
b) $ n$ is a positive integer not divisible by the cube of a prime.
2020 Yasinsky Geometry Olympiad, 6
In the triangle $ABC$ the altitude $BD$ and $CT$ are drawn, they intersect at the point $H$. The point $Q$ is the foot of the perpendicular drawn from the point $H$ on the bisector of the angle $A$. Prove that the bisector of the external angle $A$ of the triangle $ABC$, the bisector of the angle $BHC$ and the line $QM$, where $M$ is the midpoint of the segment $DT$, intersect at one point.
(Matvsh Kursky)
1966 Miklós Schweitzer, 5
A "letter $ T$" erected at point $ A$ of the $ x$-axis in the $ xy$-plane is the union of a segment $ AB$ in the upper half-plane perpendicular to the $ x$-axis and a segment $ CD$ containing $ B$ in its interior and parallel to the $ x$-axis. Show that it is impossible to erect a letter $ T$ at every point of the $ x$-axis so that the union of those erected at rational points is disjoint from the union of those erected at irrational points.
[i]A.Csaszar[/i]
2014 Postal Coaching, 2
Let $O$ be the centre of the square $ABCD$. Let $P,Q,R$ be respectively on the segments $OA,OB,OC$ such that $OP=3,OQ=5,OR=4$. Suppose $S$ is on $OD$ such that $X=AB\cap PQ,Y=BC\cap QR$ and $Z=CD\cap RS$ are collinear. Find $OS$.
1998 Akdeniz University MO, 4
Let $ABC$ be an equilateral triangle with side lenght is $1$ $cm$.Let $D \in [AB]$ is a point. Perpendiculars from $D$ to $[AC]$ and $[BC]$ intersects with $[AC]$ and $[BC]$ at points $E$ and $F$ respectively. Perpendiculars from $E$ and $F$ to $[AB]$ intersects with $[AB]$ at points $E_1$ and $F_1$. Prove that
$$[E_1F_1]=\frac{3}{4}$$
2011 Olympic Revenge, 1
Let $p, q, r, s, t \in \mathbb{R}^{*}_{+}$ satisfying:
i) $p^2 + pq + q^2 = s^2$
ii) $q^2 + qr + r^2 = t^2$
iii) $r^2 + rp + p^2 = s^2 - st + t^2$
Prove that
\[\frac{s^2 - st + t^2}{s^2t^2} = \frac{r^2}{q^2t^2} + \frac{p^2}{q^2s^2} - \frac{pr}{q^2ts}\]
2015 Stars Of Mathematics, 3
Let $ABCD$ be cyclic quadrilateral,let $\gamma$ be it's circumscribed circle and let $M$ be the midpoint of arc $AB$ of $\gamma$,which does not contain points $C,D$.The line that passes through $M$ and the intersection point of diagonals $AC,BD$,intersects $\gamma$ in $N\neq M$.
Let $P,Q$ be two points situated on $CD$,such that $\angle{AQD}=\angle{DAP}$ and $\angle{BPC}=\angle{CBQ}$.Prove that circles $\odot(NPQ)$ and $\gamma$ are tangent.
2010 District Olympiad, 3
Consider the cube $ABCDA'B'C'D'$. The bisectors of the angles $\angle A' C'A$ and $\angle A' AC'$ intersect $AA'$ and $A'C$ in the points $P$, respectively $S$. The point $M$ is the foot of the perpendicular from $A'$ on $CP$ , and $N$ is the foot of the perpendicular from $A'$ to $AS$. Point $O$ is the center of the face $ABB'A'$
a) Prove that the planes $(MNO)$ and $(AC'B)$ are parallel.
b) Calculate the distance between these planes, knowing that $AB = 1$.
2011 Dutch IMO TST, 5
Let $ABC$ be a triangle with $|AB|> |BC|$. Let $D$ be the midpoint of $AC$. Let $E$ be the intersection of the angular bisector of $\angle ABC$ and the line $AC$. Let $F$ be the point on $BE$ such that $CF$ is perpendicular to $BE$. Finally, let $G$ be the intersection of $CF$ and $BD$. Prove that $DF$ divides the line segment $EG$ into two equal parts.
2012 AMC 8, 21
Marla has a large white cube that has an edge of 10 feet. She also has enough green paint to cover 300 square feet. Marla uses all the paint to create a white square centered on each face, surrounded by a green border. What is the area of one of the white squares, in square feet?
$\textbf{(A)}\hspace{.05in}5\sqrt2 \qquad \textbf{(B)}\hspace{.05in}10 \qquad \textbf{(C)}\hspace{.05in}10\sqrt2 \qquad \textbf{(D)}\hspace{.05in}50 \qquad \textbf{(E)}\hspace{.05in}50\sqrt2 $
2011 IMAR Test, 1
Let $A_0A_1A_2$ be a triangle and let $P$ be a point in the plane, not situated on the circle $A_0A_1A_2$. The line $PA_k$ meets again the circle $A_0A_1A_2$ at point $B_k, k = 0, 1, 2$. A line $\ell$ through the point $P$ meets the line $A_{k+1}A_{k+2}$ at point $C_k, k = 0, 1, 2$. Show that the lines $B_kC_k, k = 0, 1, 2$, are concurrent and determine the locus of their concurrency point as the line $\ell$ turns about the point $P$.
2020 Tuymaada Olympiad, 6
$AK$ and $BL$ are altitudes of an acute triangle $ABC$. Point $P$ is chosen on the segment $AK$ so that $LK=LP$. The parallel to $BC$ through $P$ meets the parallel to $PL$ through $B$ at point $Q$. Prove that $\angle AQB = \angle ACB$.
[i](S. Berlov)[/i]