Let $I$ be the incenter of the acute triangle $\triangle ABC$, and $BI$, $CI$ intersect the altitude of $\triangle ABC$ through $A$ at $U$, $V$, respectively. The circle with $AI$ as a diameter intersects $\odot(ABC)$ again at $T$, and $\odot(TUV)$ intersects the segment $BC$ and $\odot(ABC)$ at $P$, $Q$, respectively. Let $R$ be another intersection of $PQ$ and $\odot(ABC)$. Show that $AR\parallel BC$.

Let $ABCD$ be a convex quadrilateral with $AB$ is not parallel to $CD$. Circle $\omega_1$ with center $O_1$ passes through $A$ and $B$, and touches segment $CD$ at $P$. Circle $\omega_2$ with center $O_2$ passes through $C$ and $D$, and touches segment $AB$ at $Q$. Let $E$ and $F$ be the intersection of circles $\omega_1$ and $\omega_2$. Prove that $EF$ bisects segment $PQ$ if and only if $BC$ is parallel to $AD$.

The best parts of grandma’s $30$ cm $ \times 30$ cm square shaped pie are the edges. For this reason grandma’s three grandchildren would like to split the pie between each other so that everyone gets the same amount (of the area) of the pie, but also of the edges. Can they cut the pie into three connected pieces like that?

Let $\omega$ be a circle with center $O$. Let $B$ and $C$ be two fixed points on the circle $\omega$ and let $A$ be a variable point on $\omega$. We denote by $X$ the intersection point of lines $OB$ and $AC$, assuming $X \neq O$. Let $\gamma$ be the circumcircle of triangle $\triangle AOX$. Let $Y$ be the second intersection point of $\gamma$ with $\omega$. The tangent to $\gamma$ at $Y$ intersects $\omega$ at $I$. The line $OI$ intersects $\omega$ at $J$. The perpendicular bisector of segment $OY$ intersects line $YI$ at $T$, and line $AJ$ intersects $\gamma$ at $P$. We denote by $Z$ the second intersection point of the circumcircle of triangle $\triangle PYT$ with $\omega$. Prove that, as point $A$ varies, points $Y$ and $Z$ remain fixed.

In the convex quadrilateral $ABCD$, point $X$ is selected on side $AD$, and the diagonals intersect at point $E$. It is known that $AC = BD$, $\angle ABX = \angle AX B = 50^o$, $\angle CAD = 51^o$, $\angle AED = 80^o$. Find the value of angle $\angle AXC$.

Let $AH_a$ and $BH_b$ be altitudes, $AL_a$ and $BL_b$ be angle bisectors of a triangle $ABC$. It is known that $H_aH_b // L_aL_b$. Is it necessarily true that $AC = BC$? (B. Frenkin)

For each positive real number $x$, let $f(x)=\frac{x}{1+x}$ . Prove that if $a$, $b,$ $c$ are the sidelengths of a triangle, then $f(a)$, $f(b),$ $f(c)$ are sidelengths of a triangle.

The base of a triangle is $ 15$ inches. Two lines are drawn parallel to the base, terminating in the other two sides, and dividing the triangle into three equal areas. The length of the parallel closer to the base is: $ \textbf{(A)}\ 5\sqrt{6}\text{ inches} \qquad\textbf{(B)}\ 10\text{ inches} \qquad\textbf{(C)}\ 4\sqrt{3}\text{ inches} \qquad\textbf{(D)}\ 7.5\text{ inches}\\ \textbf{(E)}\ \text{none of these}$

Let $n$ be positive integers. Denote the graph of $y=\sqrt{x}$ by $C,$ and the line passing through two points $(n,\ \sqrt{n})$ and $(n+1,\ \sqrt{n+1})$ by $l.$ Let $V$ be the volume of the solid obtained by revolving the region bounded by $C$ and $l$ around the $x$ axis.Find the positive numbers $a,\ b$ such that $\lim_{n\to\infty}n^{a}V=b.$

Points $M,N$ and $P$ on the sides $BC, CA$ and $AB$ of $\vartriangle ABC$ are such that $\vartriangle MNP$ is acute. Denote by $h$ and $H$ the lengths of the shortest altitude of $\vartriangle ABC$ and the longest altitude of $\vartriangle MNP$. Prove that $h \le 2H$.

[hide=R stands for Ramanujan , P stands for Pascal]they had two problem sets under those two names[/hide] [u]Set 4[/u] [b]R4.16 / P1.4[/b] Adam and Becky are building a house. Becky works twice as fast as Adam does, and they both work at constant speeds for the same amount of time each day. They plan to finish building in $6$ days. However, after $2$ days, their friend Charlie also helps with building the house. Because of this, they finish building in just $5$ days. What fraction of the house did Adam build? [b]R4.17[/b] A bag with $10$ items contains both pencils and pens. Kanye randomly chooses two items from the bag, with replacement. Suppose the probability that he chooses $1$ pen and $1$ pencil is $\frac{21}{50}$ . What are all possible values for the number of pens in the bag? [b]R4.18 / P2.8[/b] In cyclic quadrilateral $ABCD$, $\angle ABD = 40^o$, and $\angle DAC = 40^o$. Compute the measure of $\angle ADC$ in degrees. (In cyclic quadrilaterals, opposite angles sum up to $180^o$.) [b]R4.19 / P2.6[/b] There is a strange random number generator which always returns a positive integer between $1$ and $7500$, inclusive. Half of the time, it returns a uniformly random positive integer multiple of $25$, and the other half of the time, it returns a uniformly random positive integer that isn’t a multiple of $25$. What is the probability that a number returned from the generator is a multiple of $30$? [b]R4.20 / P2.7[/b] Julia is shopping for clothes. She finds $T$ different tops and $S$ different skirts that she likes, where $T \ge S > 0$. Julia can either get one top and one skirt, just one top, or just one skirt. If there are $50$ ways in which she can make her choice, what is $T - S$? [u]Set 5[/u] [b]R5.21[/b] A $5 \times 5 \times 5$ cube’s surface is completely painted blue. The cube is then completely split into $ 1 \times 1 \times 1$ cubes. What is the average number of blue faces on each $ 1 \times 1 \times 1$ cube? [b]R5.22 / P2.10[/b] Find the number of values of $n$ such that a regular $n$-gon has interior angles with integer degree measures. [b]R5.23[/b] $4$ positive integers form an geometric sequence. The sum of the $4$ numbers is $255$, and the average of the second and the fourth number is $102$. What is the smallest number in the sequence? [b]R5.24[/b] Let $S$ be the set of all positive integers which have three digits when written in base $2016$ and two digits when written in base $2017$. Find the size of $S$. [b]R5.25 / P3.12[/b] In square $ABCD$ with side length $13$, point $E$ lies on segment $CD$. Segment $AE$ divides $ABCD$ into triangle $ADE$ and quadrilateral $ABCE$. If the ratio of the area of $ADE$ to the area of $ABCE$ is $4 : 11$, what is the ratio of the perimeter of $ADE$ to the perimeter of $ABCE$? [u]Set 6[/u] [b]R6.26 / P6.25[/b] Submit a decimal n to the nearest thousandth between $0$ and $200$. Your score will be $\min (12, S)$, where $S$ is the non-negative difference between $n$ and the largest number less than or equal to $n$ chosen by another team (if you choose the smallest number, $S = n$). For example, 1.414 is an acceptable answer, while $\sqrt2$ and $1.4142$ are not. [b]R6.27 / P6.27[/b] Guang is going hard on his YNA project. From $1:00$ AM Saturday to $1:00$ AM Sunday, the probability that he is not finished with his project $x$ hours after $1:00$ AM on Saturday is $\frac{1}{x+1}$ . If Guang does not finish by 1:00 AM on Sunday, he will stop procrastinating and finish the project immediately. Find the expected number of minutes $A$ it will take for him to finish his project. An estimate of $E$ will earn $12 \cdot 2^{-|E-A|/60}$ points. [b]R6.28 / P6.28[/b] All the diagonals of a regular $100$-gon (a regular polygon with $100$ sides) are drawn. Let $A$ be the number of distinct intersection points between all the diagonals. Find $A$. An estimate of $E$ will earn $12 \cdot \left(16 \log_{10}\left(\max \left(\frac{E}{A},\frac{A}{E}\right)\right)+ 1\right)^{-\frac12}$ or $0$ points if this expression is undefined. [b]R6.29 / P6.29 [/b]Find the smallest positive integer $A$ such that the following is true: if every integer $1, 2, ..., A$ is colored either red or blue, then no matter how they are colored, there are always 6 integers among them forming an increasing arithmetic progression that are all colored the same color. An estimate of $E$ will earn $12 min \left(\frac{E}{A},\frac{A}{E}\right)$ points or $0$ points if this expression is undefined. [b]R6.30 / P6.30[/b] For all integers $n \ge 2$, let $f(n)$ denote the smallest prime factor of $n$. Find $A =\sum^{10^6}_{n=2}f(n)$. In other words, take the smallest prime factor of every integer from $2$ to $10^6$ and sum them all up to get $A$. You may find the following values helpful: there are $78498$ primes below $10^6$, $9592$ primes below $10^5$, $1229$ primes below $10^4$, and $168$ primes below $10^3$. An estimate of $E$ will earn $\max \left(0, 12-4 \log_{10}(max \left(\frac{E}{A},\frac{A}{E}\right)\right)$ or $0$ points if this expression is undefined. PS. You should use hide for answers. R1-15 /P1-5 have been posted [url=https://artofproblemsolving.com/community/c3h2786721p24495629]here[/url], and P11-25 [url=https://artofproblemsolving.com/community/c3h2786880p24497350]here[/url]. Collected [url=https://artofproblemsolving.com/community/c5h2760506p24143309]here[/url].

Let $ABCD$ be a square with the side of $20$ units. Amir divides this square into $400$ unit squares. Reza then picks $4$ of the vertices of these unit squares. These vertices lie inside the square $ABCD$ and define a rectangle with the sides parallel to the sides of the square $ABCD.$ There are exactly $24$ unit squares which have at least one point in common with the sides of this rectangle. Find all possible values for the area of a rectangle with these properties. [hide="Note"][i]Note:[/i] Vid changed to Amir, and Eva change to Reza![/hide]

On the sides of a triangle $ABC$ right angled at $A$ three points $D, E$ and $F$ (respectively $BC, AC$ and $AB$) are chosen so that the quadrilateral $AFDE$ is a square. If $x$ is the length of the side of the square, show that \[\frac{1}{x}=\frac{1}{AB}+\frac{1}{AC}\]

Let $P$ be an interior point of acute triangle $\Delta ABC$, which is different from the orthocenter. Let $D$ and $E$ be the feet of altitudes from $A$ to $BP$ and $CP$, and let $F$ and $G$ be the feet of the altitudes from $P$ to sides $AB$ and $AC$. Denote by $X$ the midpoint of $[AP]$, and let the second intersection of the circumcircles of triangles $\Delta DFX$ and $\Delta EGX$ lie on $BC$. Prove that $AP$ is perpendicular to $BC$ or $\angle PBA = \angle PCA$.

Let $S_1$ be the area of the regular pentagon $ABCDE$. And let $S_2$ be the area of the regular pentagon whose sides lie on the lines $AC, CE, EB, BD, DA$. What is values of $\frac{S_1}{S_2}$ ? $\textbf{(A)}\ \frac{41}{6} \qquad\textbf{(B)}\ \frac{3+5\sqrt5}{2} \qquad\textbf{(C)}\ 4+\sqrt5 \qquad\textbf{(D)}\ \frac{7+3\sqrt5}2 \qquad\textbf{(E)}\ \text{None}$

Two circles are given in the plane, $\Omega$ and inside it $\omega$. The center of $\omega$ is $I$. $P$ is a point moving on $\Omega$. The second intersection of the tangents from $P$ to $\omega$ and circle $\Omega$ are $Q$ and $R.$ The second intersection of circle $IQR$ and lines $PI$, $PQ$ and $PR$ are $J$, $S$ and $T,$ respectively. The reflection of point $J$ across line $ST$ is $K.$ Prove that lines $PK$ are concurrent.

A triangle has no angle greater than $90^o$. Show that the sum of the medians is greater than four times the circumradius.

Let $ABC$ be a triangle. The points $K, L,$ and $M$ lie on the segments $BC, CA,$ and $AB,$ respectively, such that the lines $AK, BL,$ and $CM$ intersect in a common point. Prove that it is possible to choose two of the triangles $ALM, BMK,$ and $CKL$ whose inradii sum up to at least the inradius of the triangle $ABC$. [i]Proposed by Estonia[/i]

On the sides $AB$ and $AD$ of the square $ABCD$, the points $N$ and $P$ are selected, respectively, so that $PN = NC$, the point $Q$ Is a point on the segment $AN$ for which $\angle NCB = \angle QPN$. Prove that $\angle BCQ = \tfrac {1} {2} \angle PQA$.

We are given triangles $ABC$ and $DEF$ such that $D\in BC, E\in CA, F\in AB$, $AD\perp EF, BE\perp FD, CF\perp DE$. Let the circumcenter of $DEF$ be $O$, and let the circumcircle of $DEF$ intersect $BC,CA,AB$ again at $R,S,T$ respectively. Prove that the perpendiculars to $BC,CA,AB$ through $D,E,F$ respectively intersect at a point $X$, and the lines $AR,BS,CT$ intersect at a point $Y$, such that $O,X,Y$ are collinear. [i]Proposed by Sammy Luo[/i]

Suppose $ABCD$ is a cyclic quadrilateral with $BC = CD$. Let $\omega$ be the circle with center $C$ tangential to the side $BD$. Let $I$ be the centre of the incircle of triangle $ABD$. Prove that the straight line passing through $I$, which is parallel to $AB$, touches the circle $\omega$.

Let $M,N, P$ be the midpoints of the sides $BC,CA,AB$ of the triangle $ABC$, respectively, and let $G$ be the centroid of the triangle. Prove that if $BMGP$ is cyclic and $2BN = \sqrt3 AB$ , then triangle $ABC$ is equilateral.

a) Two circles of radii $6$ and $24$ are tangent externally. Line $\ell$ touches the first circle at point $A$, and the second at point $B$. Find $AB$. b) The distance between the centers $O_1$ and $O_2$ of circles of radii $6$ and $24$ is $36$. Line $\ell$ touches the first circle at point $A$, and the second at point $B$ and intersects $O_1O_2$. Find $AB$.

Let $D$ be an arbitrary point on side $AB$ of triangle $ABC$. Circumcircles of triangles $BCD$ and $ACD$ intersect sides $AC$ and $BC$ at points $E$ and $F$, respectively. Perpendicular bisector of $EF$ cuts $AB$ at point $M$, and line perpendicular to $AB$ at $D$ at point $N$. Lines $AB$ and $EF$ intersect at point $T$, and the second point of intersection of circumcircle of triangle $CMD$ and line $TC$ is $U$. Prove that $NC=NU$

Let $ABCD$ be a cyclic quadrilateral, so that $|AB| + |CD| = |BC|$. Show that the intersection of the bisector of $\angle DAB$ and $\angle CDA$ lies on the side $BC$.