Found problems: 35
2024 Sharygin Geometry Olympiad, 10.7
Let $ABC$ be a triangle with $\angle A=60^\circ$; $AD$, $BE$, and $CF$ be its bisectors; $P, Q$ be the projections of $A$ to $EF$ and $BC$ respectively; and $R$ be the second common point of the circle $DEF$ with $AD$. Prove that $P, Q, R$ are collinear.
2003 JHMMC 8, 8
What is the area of a square in square feet, if each of its diagonals is $4$ feet long?
LMT Theme Rounds, 2023F 2C
Let $R$ be the rectangle on the cartesian plane with vertices $(0,0)$, $(5,0)$, $(5,7)$, and $(0,7)$. Find the number of squares with sides parallel to the axes and vertices that are lattice points that lie within the region bounded by $R$.
[i]Proposed by Boyan Litchev[/i]
[hide=Solution][i]Solution[/i]. $\boxed{85}$
We have $(6-n)(8-n)$ distinct squares with side length $n$, so the total number of squares is $5 \cdot 7+4 \cdot 6+3 \cdot 5+2 \cdot 4+1\cdot 3 = \boxed{85}$.[/hide]
2024 Sharygin Geometry Olympiad, 9.2
Points $A, B, C, D$ on the plane do not form a rectangle. Let the sidelengths of triangle $T$ equal $AB+CD$, $AC+BD$, $AD+BC$. Prove that the triangle $T$ is acute-angled.
2023 LMT Fall, 2C
Let $R$ be the rectangle on the cartesian plane with vertices $(0,0)$, $(5,0)$, $(5,7)$, and $(0,7)$. Find the number of squares with sides parallel to the axes and vertices that are lattice points that lie within the region bounded by $R$.
[i]Proposed by Boyan Litchev[/i]
[hide=Solution][i]Solution[/i]. $\boxed{85}$
We have $(6-n)(8-n)$ distinct squares with side length $n$, so the total number of squares is $5 \cdot 7+4 \cdot 6+3 \cdot 5+2 \cdot 4+1\cdot 3 = \boxed{85}$.[/hide]
2024 Sharygin Geometry Olympiad, 10.1
The diagonals of a cyclic quadrilateral $ABCD$ meet at point $P$. The bisector of angle $ABD$ meets $AC$ at point $E$, and the bisector of angle $ACD$ meets $BD$ at point $F$. Prove that the lines $AF$ and $DE$ meet on the median of triangle $APD$.
LMT Theme Rounds, 2023F 4B
In triangle $ABC$, $AB = 13$, $BC = 14$, and $CA = 15$. Let $M$ be the midpoint of side $AB$, $G$ be the centroid of $\triangle ABC$, and $E$ be the foot of the altitude from $A$ to $BC$. Compute the area of quadrilateral $GAME$.
[i]Proposed by Evin Liang[/i]
[hide=Solution][i]Solution[/i]. $\boxed{23}$
Use coordinates with $A = (0,12)$, $B = (5,0)$, and $C = (-9,0)$. Then $M = \left(\dfrac{5}{2},6\right)$ and $E = (0,0)$. By shoelace, the area of $GAME$ is $\boxed{23}$.[/hide]
2023 LMT Fall, 1C
How many distinct triangles are there with prime side lengths and perimeter $100$?
[i]Proposed by Muztaba Syed[/i]
[hide=Solution][i]Solution.[/i] $\boxed{0}$
As the perimeter is even, $1$ of the sides must be $2$. Thus, the other $2$ sides are congruent by Triangle Inequality. Thus, for the perimeter to be $100$, both of the other sides must be $49$, but as $49$ is obviously composite, the answer is thus $\boxed{0}$.[/hide]
2024 Sharygin Geometry Olympiad, 10.3
Let $BE$ and $CF$ be the bisectors of a triangle $ABC$. Prove that $2EF \leq BF + CE$.
2024 Sharygin Geometry Olympiad, 9.6
The incircle of a triangle $ABC$ centered at $I$ touches the sides $BC, CA$, and $AB$ at points $A_1, B_1, $ and $C_1$ respectively. The excircle centered at $J$ touches the side $AC$ at point $B_2$ and touches the extensions of $AB, BC$ at points $C_2, A_2$ respectively. Let the lines $IB_2$ and $JB_1$ meet at point $X$, the lines $IC_2$ and $JC_1$ meet at point $Y$, the lines $IA_2$ and $JA_1$ meet at point $Z$. Prove that if one of points $X, Y, Z$ lies on the incircle then two remaining points also lie on it.