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Let $X Y Z$ be a triangle with $\angle X Y Z=40^{\circ}$ and $\angle Y Z X=60^{\circ}$. A circle $\Gamma$, centered at the point $I$, lies inside triangle $X Y Z$ and is tangent to all three sides of the triangle. Let $A$ be the point of tangency of $\Gamma$ with $Y Z$, and let ray $\overrightarrow{X I}$ intersect side $Y Z$ at $B$. Determine the measure of $\angle A I B$. | 10^{\circ} | 0 |
Over all real numbers $x$ and $y$, find the minimum possible value of $$ (x y)^{2}+(x+7)^{2}+(2 y+7)^{2} $$ | 45 | 0 |
Let P_{1}, P_{2}, \ldots, P_{6} be points in the complex plane, which are also roots of the equation x^{6}+6 x^{3}-216=0. Given that P_{1} P_{2} P_{3} P_{4} P_{5} P_{6} is a convex hexagon, determine the area of this hexagon. | 9 \sqrt{3} | 0 |
For dessert, Melinda eats a spherical scoop of ice cream with diameter 2 inches. She prefers to eat her ice cream in cube-like shapes, however. She has a special machine which, given a sphere placed in space, cuts it through the planes $x=n, y=n$, and $z=n$ for every integer $n$ (not necessarily positive). Melinda centers the scoop of ice cream uniformly at random inside the cube $0 \leq x, y, z \leq 1$, and then cuts it into pieces using her machine. What is the expected number of pieces she cuts the ice cream into? | 7+\frac{13 \pi}{3} | 0 |
A binary tree is a tree in which each node has exactly two descendants. Suppose that each node of the tree is coloured black with probability \(p\), and white otherwise, independently of all other nodes. For any path \(\pi\) containing \(n\) nodes beginning at the root of the tree, let \(B(\pi)\) be the number of black nodes in \(\pi\), and let \(X_{n}(k)\) be the number of such paths \(\pi\) for which \(B(\pi) \geq k\). (1) Show that there exists \(\beta_{c}\) such that \(\lim _{n \rightarrow \infty} \mathbb{E}\left(X_{n}(\beta n)\right)= \begin{cases}0, & \text { if } \beta>\beta_{c} \\ \infty, & \text { if } \beta<\beta_{c}\end{cases}\) How to determine the value of \(\beta_{c}\) ? (2) For \(\beta \neq \beta_{c}\), find the limit \(\lim _{n \rightarrow \infty} \mathbb{P}\left(X_{n}(\beta n) \geq 1\right)\). | Existence of \(\beta_{c}\) and limits as described in the solution. | 0 |
Carl only eats food in the shape of equilateral pentagons. Unfortunately, for dinner he receives a piece of steak in the shape of an equilateral triangle. So that he can eat it, he cuts off two corners with straight cuts to form an equilateral pentagon. The set of possible perimeters of the pentagon he obtains is exactly the interval $[a, b)$, where $a$ and $b$ are positive real numbers. Compute $\frac{a}{b}$. | 4 \sqrt{3}-6 | 0 |
Let $A B C D$ be a quadrilateral with an inscribed circle $\omega$ that has center $I$. If $I A=5, I B=7, I C=4, I D=9$, find the value of $\frac{A B}{C D}$. | \frac{35}{36} | 0 |
Equilateral triangle $ABC$ has circumcircle $\Omega$. Points $D$ and $E$ are chosen on minor arcs $AB$ and $AC$ of $\Omega$ respectively such that $BC=DE$. Given that triangle $ABE$ has area 3 and triangle $ACD$ has area 4, find the area of triangle $ABC$. | \frac{37}{7} | 0 |
A cylinder with radius 15 and height 16 is inscribed in a sphere. Three congruent smaller spheres of radius $x$ are externally tangent to the base of the cylinder, externally tangent to each other, and internally tangent to the large sphere. What is the value of $x$? | \frac{15 \sqrt{37}-75}{4} | 0 |
Find the number of integers $n$ with $1 \leq n \leq 2017$ so that $(n-2)(n-0)(n-1)(n-7)$ is an integer multiple of 1001. | 99 | 0 |
Compute the smallest positive integer $n$ for which $\sqrt{100+\sqrt{n}}+\sqrt{100-\sqrt{n}}$ is an integer. | 6156 | 0 |
Suppose that there are initially eight townspeople and one goon. One of the eight townspeople is named Jester. If Jester is sent to jail during some morning, then the game ends immediately in his sole victory. (However, the Jester does not win if he is sent to jail during some night.) Find the probability that only the Jester wins. | \frac{1}{3} | 0 |
To celebrate 2019, Faraz gets four sandwiches shaped in the digits 2, 0, 1, and 9 at lunch. However, the four digits get reordered (but not flipped or rotated) on his plate and he notices that they form a 4-digit multiple of 7. What is the greatest possible number that could have been formed? | 1092 | 0 |
A square in the $xy$-plane has area $A$, and three of its vertices have $x$-coordinates 2, 0, and 18 in some order. Find the sum of all possible values of $A$. | 1168 | 0 |
Find all ordered pairs $(a, b)$ of positive integers such that $2 a+1$ divides $3 b-1$ and $2 b+1$ divides $3 a-1$. | (2,2),(12,17),(17,12) | 0 |
Let $\mathcal{P}$ be a parabola with focus $F$ and directrix $\ell$. A line through $F$ intersects $\mathcal{P}$ at two points $A$ and $B$. Let $D$ and $C$ be the feet of the altitudes from $A$ and $B$ onto $\ell$, respectively. Given that $AB=20$ and $CD=14$, compute the area of $ABCD$. | 140 | 0 |
For breakfast, Milan is eating a piece of toast shaped like an equilateral triangle. On the piece of toast rests a single sesame seed that is one inch away from one side, two inches away from another side, and four inches away from the third side. He places a circular piece of cheese on top of the toast that is tangent to each side of the triangle. What is the area of this piece of cheese? | \frac{49 \pi}{9} | 0 |
How many integers $n$ in the set $\{4,9,14,19, \ldots, 2014\}$ have the property that the sum of the decimal digits of $n$ is even? | 201 | 0 |
Each of the integers $1,2, \ldots, 729$ is written in its base-3 representation without leading zeroes. The numbers are then joined together in that order to form a continuous string of digits: $12101112202122 \ldots \ldots$ How many times in this string does the substring 012 appear? | 148 | 0 |
A convex 2019-gon \(A_{1}A_{2}\ldots A_{2019}\) is cut into smaller pieces along its 2019 diagonals of the form \(A_{i}A_{i+3}\) for \(1 \leq i \leq 2019\), where \(A_{2020}=A_{1}, A_{2021}=A_{2}\), and \(A_{2022}=A_{3}\). What is the least possible number of resulting pieces? | 5049 | 0 |
Let $\pi$ be a permutation of the numbers from 2 through 2012. Find the largest possible value of $\log _{2} \pi(2) \cdot \log _{3} \pi(3) \cdots \log _{2012} \pi(2012)$. | 1 | 0 |
The vertices of a regular nonagon are colored such that 1) adjacent vertices are different colors and 2) if 3 vertices form an equilateral triangle, they are all different colors. Let m be the minimum number of colors needed for a valid coloring, and n be the total number of colorings using m colors. Determine mn. (Assume each vertex is distinguishable.) | 54 | 0 |
2019 students are voting on the distribution of \(N\) items. For each item, each student submits a vote on who should receive that item, and the person with the most votes receives the item (in case of a tie, no one gets the item). Suppose that no student votes for the same person twice. Compute the maximum possible number of items one student can receive, over all possible values of \(N\) and all possible ways of voting. | 1009 | 0 |
Meghana writes two (not necessarily distinct) primes $q$ and $r$ in base 10 next to each other on a blackboard, resulting in the concatenation of $q$ and $r$ (for example, if $q=13$ and $r=5$, the number on the blackboard is now 135). She notices that three more than the resulting number is the square of a prime $p$. Find all possible values of $p$. | 5 | 0 |
Real numbers $x, y$, and $z$ are chosen from the interval $[-1,1]$ independently and uniformly at random. What is the probability that $|x|+|y|+|z|+|x+y+z|=|x+y|+|y+z|+|z+x|$? | \frac{3}{8} | 0 |
Will stands at a point \(P\) on the edge of a circular room with perfectly reflective walls. He shines two laser pointers into the room, forming angles of \(n^{\circ}\) and \((n+1)^{\circ}\) with the tangent at \(P\), where \(n\) is a positive integer less than 90. The lasers reflect off of the walls, illuminating the points they hit on the walls, until they reach \(P\) again. (\(P\) is also illuminated at the end.) What is the minimum possible number of illuminated points on the walls of the room? | 28 | 0 |
Let $a, b$, and $c$ be real numbers. Consider the system of simultaneous equations in variables $x$ and $y:$ $a x+b y =c-1$ and $(a+5) x+(b+3) y =c+1$. Determine the value(s) of $c$ in terms of $a$ such that the system always has a solution for any $a$ and $b$. | 2a/5 + 1 \text{ or } \frac{2a+5}{5} | 0 |
A triangle $X Y Z$ and a circle $\omega$ of radius 2 are given in a plane, such that $\omega$ intersects segment $\overline{X Y}$ at the points $A, B$, segment $\overline{Y Z}$ at the points $C, D$, and segment $\overline{Z X}$ at the points $E, F$. Suppose that $X B>X A, Y D>Y C$, and $Z F>Z E$. In addition, $X A=1, Y C=2, Z E=3$, and $A B=C D=E F$. Compute $A B$. | \sqrt{10}-1 | 0 |
Assume that \(X_{1}, \ldots, X_{n} \sim U[0,1]\) (uniform distribution) are i.i.d. Denote \(X_{(1)}=\min _{1 \leq k \leq n} X_{k}\) and \(X_{(n)}=\max _{1 \leq k \leq n} X_{k}\). Let \(R=X_{(n)}-X_{(1)}\) be the sample range and \(V=\left(X_{(1)}+X_{(n)}\right) / 2\) be the sample midvalue. (1). Find the joint density of \(\left(X_{(1)}, X_{(n)}\right)\). (2). Find the joint density of \((R, V)\). (3). Find the density of \(R\) and the density of \(V\). | Joint density of \(\left(X_{(1)}, X_{(n)}\right)\), joint density of \((R, V)\), density of \(R\), and density of \(V\) as described in the solution. | 0 |
Given that $a, b, c$ are integers with $a b c=60$, and that complex number $\omega \neq 1$ satisfies $\omega^{3}=1$, find the minimum possible value of $\left|a+b \omega+c \omega^{2}\right|$. | \sqrt{3} | 0 |
Determine the set of all real numbers $p$ for which the polynomial $Q(x)=x^{3}+p x^{2}-p x-1$ has three distinct real roots. | p>1 \text{ and } p<-3 | 0 |
Let $a, b, c$ be positive integers such that $\frac{a}{77}+\frac{b}{91}+\frac{c}{143}=1$. What is the smallest possible value of $a+b+c$? | 79 | 0 |
Mark and William are playing a game with a stored value. On his turn, a player may either multiply the stored value by 2 and add 1 or he may multiply the stored value by 4 and add 3. The first player to make the stored value exceed $2^{100}$ wins. The stored value starts at 1 and Mark goes first. Assuming both players play optimally, what is the maximum number of times that William can make a move? | 33 | 0 |
In-Young generates a string of $B$ zeroes and ones using the following method:
- First, she flips a fair coin. If it lands heads, her first digit will be a 0, and if it lands tails, her first digit will be a 1.
- For each subsequent bit, she flips an unfair coin, which lands heads with probability $A$. If the coin lands heads, she writes down the number (zero or one) different from previous digit, while if the coin lands tails, she writes down the previous digit again.
What is the expected value of the number of zeroes in her string? | 2 | 0 |
Pascal has a triangle. In the $n$th row, there are $n+1$ numbers $a_{n, 0}, a_{n, 1}, a_{n, 2}, \ldots, a_{n, n}$ where $a_{n, 0}=a_{n, n}=1$. For all $1 \leq k \leq n-1, a_{n, k}=a_{n-1, k}-a_{n-1, k-1}$. Let $N$ be the value of the sum $$\sum_{k=0}^{2018} \frac{\left|a_{2018, k}\right|}{\binom{2018}{k}}$$ Estimate $N$. | 780.9280674537 | 0 |
For any positive integers $a$ and $b$, define $a \oplus b$ to be the result when adding $a$ to $b$ in binary (base 2), neglecting any carry-overs. For example, $20 \oplus 14=10100_{2} \oplus 1110_{2}=11010_{2}=26$. (The operation $\oplus$ is called the exclusive or.) Compute the sum $$\sum_{k=0}^{2^{2014}-1}\left(k \oplus\left\lfloor\frac{k}{2}\right\rfloor\right)$$ Here $\lfloor x\rfloor$ is the greatest integer not exceeding $x$. | 2^{2013}\left(2^{2014}-1\right) \text{ OR } 2^{4027}-2^{2013} | 0 |
Katie has a fair 2019-sided die with sides labeled $1,2, \ldots, 2019$. After each roll, she replaces her $n$-sided die with an $(n+1)$-sided die having the $n$ sides of her previous die and an additional side with the number she just rolled. What is the probability that Katie's $2019^{\text {th }}$ roll is a 2019? | \frac{1}{2019} | 0 |
Alice is bored in class, so she thinks of a positive integer. Every second after that, she subtracts from her current number its smallest prime divisor, possibly itself. After 2022 seconds, she realizes that her number is prime. Find the sum of all possible values of her initial number. | 8093 | 0 |
Let $n$ be the answer to this problem. The polynomial $x^{n}+ax^{2}+bx+c$ has real coefficients and exactly $k$ real roots. Find the sum of the possible values of $k$. | 10 | 0 |
Let $A B C D$ be an isosceles trapezoid with $A D=B C=255$ and $A B=128$. Let $M$ be the midpoint of $C D$ and let $N$ be the foot of the perpendicular from $A$ to $C D$. If $\angle M B C=90^{\circ}$, compute $\tan \angle N B M$. | \frac{120}{353} | 0 |
In rectangle $A B C D$ with area 1, point $M$ is selected on $\overline{A B}$ and points $X, Y$ are selected on $\overline{C D}$ such that $A X<A Y$. Suppose that $A M=B M$. Given that the area of triangle $M X Y$ is $\frac{1}{2014}$, compute the area of trapezoid $A X Y B$. | \frac{1}{2}+\frac{1}{2014} \text{ OR } \frac{504}{1007} | 0 |
How many ways are there to arrange three indistinguishable rooks on a $6 \times 6$ board such that no two rooks are attacking each other? | 2400 | 0 |
Let $n$ be the answer to this problem. Given $n>0$, find the number of distinct (i.e. non-congruent), non-degenerate triangles with integer side lengths and perimeter $n$. | 48 | 0 |
Let $n$ be the answer to this problem. Box $B$ initially contains $n$ balls, and Box $A$ contains half as many balls as Box $B$. After 80 balls are moved from Box $A$ to Box $B$, the ratio of balls in Box $A$ to Box $B$ is now $\frac{p}{q}$, where $p, q$ are positive integers with $\operatorname{gcd}(p, q)=1$. Find $100p+q$. | 720 | 0 |
Let $n$ be the answer to this problem. Hexagon $ABCDEF$ is inscribed in a circle of radius 90. The area of $ABCDEF$ is $8n$, $AB=BC=DE=EF$, and $CD=FA$. Find the area of triangle $ABC$. | 2592 | 0 |
Plot points $A, B, C$ at coordinates $(0,0),(0,1)$, and $(1,1)$ in the plane, respectively. Let $S$ denote the union of the two line segments $A B$ and $B C$. Let $X_{1}$ be the area swept out when Bobby rotates $S$ counterclockwise 45 degrees about point $A$. Let $X_{2}$ be the area swept out when Calvin rotates $S$ clockwise 45 degrees about point $A$. Find $\frac{X_{1}+X_{2}}{2}$. | \frac{\pi}{4} | 0 |
Find the number of ordered 2012-tuples of integers $\left(x_{1}, x_{2}, \ldots, x_{2012}\right)$, with each integer between 0 and 2011 inclusive, such that the sum $x_{1}+2 x_{2}+3 x_{3}+\cdots+2012 x_{2012}$ is divisible by 2012. | 2012^{2011} | 0 |
Let $A B C$ be an isosceles triangle with $A B=A C$. Let $D$ and $E$ be the midpoints of segments $A B$ and $A C$, respectively. Suppose that there exists a point $F$ on ray $\overrightarrow{D E}$ outside of $A B C$ such that triangle $B F A$ is similar to triangle $A B C$. Compute $\frac{A B}{B C}$. | \sqrt{2} | 0 |
Compute the sum of all positive real numbers \(x \leq 5\) satisfying \(x=\frac{\left\lceil x^{2}\right\rceil+\lceil x\rceil \cdot\lfloor x\rfloor}{\lceil x\rceil+\lfloor x\rfloor}\). | 85 | 0 |
In \(\triangle ABC\), the external angle bisector of \(\angle BAC\) intersects line \(BC\) at \(D\). \(E\) is a point on ray \(\overrightarrow{AC}\) such that \(\angle BDE=2 \angle ADB\). If \(AB=10, AC=12\), and \(CE=33\), compute \(\frac{DB}{DE}\). | \frac{2}{3} | 0 |
Let $T$ be a trapezoid with two right angles and side lengths $4,4,5$, and $\sqrt{17}$. Two line segments are drawn, connecting the midpoints of opposite sides of $T$ and dividing $T$ into 4 regions. If the difference between the areas of the largest and smallest of these regions is $d$, compute $240 d$. | 120 | 0 |
Find the largest real number $\lambda$ such that $a^{2}+b^{2}+c^{2}+d^{2} \geq a b+\lambda b c+c d$ for all real numbers $a, b, c, d$. | \frac{3}{2} | 0 |
Call a polygon normal if it can be inscribed in a unit circle. How many non-congruent normal polygons are there such that the square of each side length is a positive integer? | 14 | 0 |
A sphere is centered at a point with integer coordinates and passes through the three points $(2,0,0)$, $(0,4,0),(0,0,6)$, but not the origin $(0,0,0)$. If $r$ is the smallest possible radius of the sphere, compute $r^{2}$. | 51 | 0 |
Let $n$ be the answer to this problem. We define the digit sum of a date as the sum of its 4 digits when expressed in mmdd format (e.g. the digit sum of 13 May is $0+5+1+3=9$). Find the number of dates in the year 2021 with digit sum equal to the positive integer $n$. | 15 | 0 |
Alice and Bob stand atop two different towers in the Arctic. Both towers are a positive integer number of meters tall and are a positive (not necessarily integer) distance away from each other. One night, the sea between them has frozen completely into reflective ice. Alice shines her flashlight directly at the top of Bob's tower, and Bob shines his flashlight at the top of Alice's tower by first reflecting it off the ice. The light from Alice's tower travels 16 meters to get to Bob's tower, while the light from Bob's tower travels 26 meters to get to Alice's tower. Assuming that the lights are both shone from exactly the top of their respective towers, what are the possibilities for the height of Alice's tower? | 7,15 | 0 |
In Middle-Earth, nine cities form a 3 by 3 grid. The top left city is the capital of Gondor and the bottom right city is the capital of Mordor. How many ways can the remaining cities be divided among the two nations such that all cities in a country can be reached from its capital via the grid-lines without passing through a city of the other country? | 30 | 0 |
Call a number feared if it contains the digits 13 as a contiguous substring and fearless otherwise. (For example, 132 is feared, while 123 is fearless.) Compute the smallest positive integer $n$ such that there exists a positive integer $a<100$ such that $n$ and $n+10 a$ are fearless while $n+a, n+2 a, \ldots, n+9 a$ are all feared. | 1287 | 0 |
Let $A B C$ be a triangle with $\angle B=90^{\circ}$. Given that there exists a point $D$ on $A C$ such that $A D=D C$ and $B D=B C$, compute the value of the ratio $\frac{A B}{B C}$. | \sqrt{3} | 0 |
For any finite sequence of positive integers \pi, let $S(\pi)$ be the number of strictly increasing subsequences in \pi with length 2 or more. For example, in the sequence $\pi=\{3,1,2,4\}$, there are five increasing sub-sequences: $\{3,4\},\{1,2\},\{1,4\},\{2,4\}$, and $\{1,2,4\}$, so $S(\pi)=5$. In an eight-player game of Fish, Joy is dealt six cards of distinct values, which she puts in a random order \pi from left to right in her hand. Determine $\sum_{\pi} S(\pi)$ where the sum is taken over all possible orders \pi of the card values. | 8287 | 0 |
Let $a, b, c$ be positive real numbers such that $a \leq b \leq c \leq 2 a$. Find the maximum possible value of $$\frac{b}{a}+\frac{c}{b}+\frac{a}{c}$$ | \frac{7}{2} | 0 |
Horizontal parallel segments $A B=10$ and $C D=15$ are the bases of trapezoid $A B C D$. Circle $\gamma$ of radius 6 has center within the trapezoid and is tangent to sides $A B, B C$, and $D A$. If side $C D$ cuts out an arc of $\gamma$ measuring $120^{\circ}$, find the area of $A B C D$. | \frac{225}{2} | 0 |
Let $G_{1} G_{2} G_{3}$ be a triangle with $G_{1} G_{2}=7, G_{2} G_{3}=13$, and $G_{3} G_{1}=15$. Let $G_{4}$ be a point outside triangle $G_{1} G_{2} G_{3}$ so that ray $\overrightarrow{G_{1} G_{4}}$ cuts through the interior of the triangle, $G_{3} G_{4}=G_{4} G_{2}$, and $\angle G_{3} G_{1} G_{4}=30^{\circ}$. Let $G_{3} G_{4}$ and $G_{1} G_{2}$ meet at $G_{5}$. Determine the length of segment $G_{2} G_{5}$. | \frac{169}{23} | 0 |
Anders is solving a math problem, and he encounters the expression $\sqrt{15!}$. He attempts to simplify this radical by expressing it as $a \sqrt{b}$ where $a$ and $b$ are positive integers. The sum of all possible distinct values of $ab$ can be expressed in the form $q \cdot 15!$ for some rational number $q$. Find $q$. | 4 | 0 |
How many ways are there to arrange the numbers \(\{1,2,3,4,5,6,7,8\}\) in a circle so that every two adjacent elements are relatively prime? Consider rotations and reflections of the same arrangement to be indistinguishable. | 36 | 0 |
One hundred points labeled 1 to 100 are arranged in a $10 \times 10$ grid such that adjacent points are one unit apart. The labels are increasing left to right, top to bottom (so the first row has labels 1 to 10 , the second row has labels 11 to 20, and so on). Convex polygon $\mathcal{P}$ has the property that every point with a label divisible by 7 is either on the boundary or in the interior of $\mathcal{P}$. Compute the smallest possible area of $\mathcal{P}$. | 63 | 0 |
Let $z$ be a complex number and $k$ a positive integer such that $z^{k}$ is a positive real number other than 1. Let $f(n)$ denote the real part of the complex number $z^{n}$. Assume the parabola $p(n)=an^{2}+bn+c$ intersects $f(n)$ four times, at $n=0,1,2,3$. Assuming the smallest possible value of $k$, find the largest possible value of $a$. | \frac{1}{3} | 0 |
Let $r_{1}, r_{2}, r_{3}, r_{4}$ be the four roots of the polynomial $x^{4}-4 x^{3}+8 x^{2}-7 x+3$. Find the value of $\frac{r_{1}^{2}}{r_{2}^{2}+r_{3}^{2}+r_{4}^{2}}+\frac{r_{2}^{2}}{r_{1}^{2}+r_{3}^{2}+r_{4}^{2}}+\frac{r_{3}^{2}}{r_{1}^{2}+r_{2}^{2}+r_{4}^{2}}+\frac{r_{4}^{2}}{r_{1}^{2}+r_{2}^{2}+r_{3}^{2}}$ | -4 | 0 |
Let $\alpha$ and $\beta$ be reals. Find the least possible value of $(2 \cos \alpha+5 \sin \beta-8)^{2}+(2 \sin \alpha+5 \cos \beta-15)^{2}$. | 100 | 0 |
How many functions $f:\{1,2, \ldots, 2013\} \rightarrow\{1,2, \ldots, 2013\}$ satisfy $f(j)<f(i)+j-i$ for all integers $i, j$ such that $1 \leq i<j \leq 2013$ ? | \binom{4025}{2013} | 0 |
$A B C D$ is a parallelogram satisfying $A B=7, B C=2$, and $\angle D A B=120^{\circ}$. Parallelogram $E C F A$ is contained in $A B C D$ and is similar to it. Find the ratio of the area of $E C F A$ to the area of $A B C D$. | \frac{39}{67} | 0 |
Consider triangle $A B C$ where $B C=7, C A=8$, and $A B=9$. $D$ and $E$ are the midpoints of $B C$ and $C A$, respectively, and $A D$ and $B E$ meet at $G$. The reflection of $G$ across $D$ is $G^{\prime}$, and $G^{\prime} E$ meets $C G$ at $P$. Find the length $P G$. | \frac{\sqrt{145}}{9} | 0 |
Compute the number of ordered pairs of integers $(x, y)$ such that $x^{2}+y^{2}<2019$ and $$x^{2}+\min (x, y)=y^{2}+\max (x, y)$$ | 127 | 0 |
Nine fair coins are flipped independently and placed in the cells of a 3 by 3 square grid. Let $p$ be the probability that no row has all its coins showing heads and no column has all its coins showing tails. If $p=\frac{a}{b}$ for relatively prime positive integers $a$ and $b$, compute $100 a+b$. | 8956 | 0 |
In triangle $A B C$ with $A B=8$ and $A C=10$, the incenter $I$ is reflected across side $A B$ to point $X$ and across side $A C$ to point $Y$. Given that segment $X Y$ bisects $A I$, compute $B C^{2}$. | 84 | 0 |
Consider a $7 \times 7$ grid of squares. Let $f:\{1,2,3,4,5,6,7\} \rightarrow\{1,2,3,4,5,6,7\}$ be a function; in other words, $f(1), f(2), \ldots, f(7)$ are each (not necessarily distinct) integers from 1 to 7 . In the top row of the grid, the numbers from 1 to 7 are written in order; in every other square, $f(x)$ is written where $x$ is the number above the square. How many functions have the property that the bottom row is identical to the top row, and no other row is identical to the top row? | 1470 | 0 |
Let $A B C D$ be a cyclic quadrilateral, and let segments $A C$ and $B D$ intersect at $E$. Let $W$ and $Y$ be the feet of the altitudes from $E$ to sides $D A$ and $B C$, respectively, and let $X$ and $Z$ be the midpoints of sides $A B$ and $C D$, respectively. Given that the area of $A E D$ is 9, the area of $B E C$ is 25, and $\angle E B C-\angle E C B=30^{\circ}$, then compute the area of $W X Y Z$. | 17+\frac{15}{2} \sqrt{3} | 0 |
Consider an equilateral triangular grid $G$ with 20 points on a side, where each row consists of points spaced 1 unit apart. More specifically, there is a single point in the first row, two points in the second row, ..., and 20 points in the last row, for a total of 210 points. Let $S$ be a closed non-selfintersecting polygon which has 210 vertices, using each point in $G$ exactly once. Find the sum of all possible values of the area of $S$. | 52 \sqrt{3} | 0 |
A Vandal and a Moderator are editing a Wikipedia article. The article originally is error-free. Each day, the Vandal introduces one new error into the Wikipedia article. At the end of the day, the moderator checks the article and has a $2 / 3$ chance of catching each individual error still in the article. After 3 days, what is the probability that the article is error-free? | \frac{416}{729} | 0 |
Begining at a vertex, an ant crawls between the vertices of a regular octahedron. After reaching a vertex, it randomly picks a neighboring vertex (sharing an edge) and walks to that vertex along the adjoining edge (with all possibilities equally likely.) What is the probability that after walking along 2006 edges, the ant returns to the vertex where it began? | \frac{2^{2005}+1}{3 \cdot 2^{2006}} | 0 |
For odd primes $p$, let $f(p)$ denote the smallest positive integer $a$ for which there does not exist an integer $n$ satisfying $p \mid n^{2}-a$. Estimate $N$, the sum of $f(p)^{2}$ over the first $10^{5}$ odd primes $p$. An estimate of $E>0$ will receive $\left\lfloor 22 \min (N / E, E / N)^{3}\right\rfloor$ points. | 2266067 | 0 |
In the alphametic $W E \times E Y E=S C E N E$, each different letter stands for a different digit, and no word begins with a 0. The $W$ in this problem has the same value as the $W$ in problem 31. Find $S$. | 5 | 0 |
Two sides of a regular $n$-gon are extended to meet at a $28^{\circ}$ angle. What is the smallest possible value for $n$? | 45 | 0 |
Let $A B C$ be a triangle with $A B=2, C A=3, B C=4$. Let $D$ be the point diametrically opposite $A$ on the circumcircle of $A B C$, and let $E$ lie on line $A D$ such that $D$ is the midpoint of $\overline{A E}$. Line $l$ passes through $E$ perpendicular to $\overline{A E}$, and $F$ and $G$ are the intersections of the extensions of $\overline{A B}$ and $\overline{A C}$ with $l$. Compute $F G$. | \frac{1024}{45} | 0 |
Compute the positive integer less than 1000 which has exactly 29 positive proper divisors. | 720 | 0 |
Let $\triangle A B C$ be a triangle inscribed in a unit circle with center $O$. Let $I$ be the incenter of $\triangle A B C$, and let $D$ be the intersection of $B C$ and the angle bisector of $\angle B A C$. Suppose that the circumcircle of $\triangle A D O$ intersects $B C$ again at a point $E$ such that $E$ lies on $I O$. If $\cos A=\frac{12}{13}$, find the area of $\triangle A B C$. | \frac{15}{169} | 0 |
Find all positive integers $n>1$ for which $\frac{n^{2}+7 n+136}{n-1}$ is the square of a positive integer. | 5, 37 | 0 |
There are 100 houses in a row on a street. A painter comes and paints every house red. Then, another painter comes and paints every third house (starting with house number 3) blue. Another painter comes and paints every fifth house red (even if it is already red), then another painter paints every seventh house blue, and so forth, alternating between red and blue, until 50 painters have been by. After this is finished, how many houses will be red? | 52 | 0 |
Points $A, C$, and $B$ lie on a line in that order such that $A C=4$ and $B C=2$. Circles $\omega_{1}, \omega_{2}$, and $\omega_{3}$ have $\overline{B C}, \overline{A C}$, and $\overline{A B}$ as diameters. Circle $\Gamma$ is externally tangent to $\omega_{1}$ and $\omega_{2}$ at $D$ and $E$ respectively, and is internally tangent to $\omega_{3}$. Compute the circumradius of triangle $C D E$. | \frac{2}{3} | 0 |
There are \(n\) girls \(G_{1}, \ldots, G_{n}\) and \(n\) boys \(B_{1}, \ldots, B_{n}\). A pair \((G_{i}, B_{j})\) is called suitable if and only if girl \(G_{i}\) is willing to marry boy \(B_{j}\). Given that there is exactly one way to pair each girl with a distinct boy that she is willing to marry, what is the maximal possible number of suitable pairs? | \frac{n(n+1)}{2} | 0 |
Find the maximum possible number of diagonals of equal length in a convex hexagon. | 7 | 0 |
Let $Y$ be as in problem 14. Find the maximum $Z$ such that three circles of radius $\sqrt{Z}$ can simultaneously fit inside an equilateral triangle of area $Y$ without overlapping each other. | 10 \sqrt{3}-15 | 0 |
Spencer is making burritos, each of which consists of one wrap and one filling. He has enough filling for up to four beef burritos and three chicken burritos. However, he only has five wraps for the burritos; in how many orders can he make exactly five burritos? | 25 | 0 |
Let $a \geq b \geq c$ be real numbers such that $$\begin{aligned} a^{2} b c+a b^{2} c+a b c^{2}+8 & =a+b+c \\ a^{2} b+a^{2} c+b^{2} c+b^{2} a+c^{2} a+c^{2} b+3 a b c & =-4 \\ a^{2} b^{2} c+a b^{2} c^{2}+a^{2} b c^{2} & =2+a b+b c+c a \end{aligned}$$ If $a+b+c>0$, then compute the integer nearest to $a^{5}$. | 1279 | 0 |
A sequence is defined by $A_{0}=0, A_{1}=1, A_{2}=2$, and, for integers $n \geq 3$, $$A_{n}=\frac{A_{n-1}+A_{n-2}+A_{n-3}}{3}+\frac{1}{n^{4}-n^{2}}$$ Compute $\lim _{N \rightarrow \infty} A_{N}$. | \frac{13}{6}-\frac{\pi^{2}}{12} | 0 |
In a game, there are three indistinguishable boxes; one box contains two red balls, one contains two blue balls, and the last contains one ball of each color. To play, Raj first predicts whether he will draw two balls of the same color or two of different colors. Then, he picks a box, draws a ball at random, looks at the color, and replaces the ball in the same box. Finally, he repeats this; however, the boxes are not shuffled between draws, so he can determine whether he wants to draw again from the same box. Raj wins if he predicts correctly; if he plays optimally, what is the probability that he will win? | \frac{5}{6} | 0 |
Let $a_{0}, a_{1}, a_{2}, \ldots$ be a sequence of real numbers defined by $a_{0}=21, a_{1}=35$, and $a_{n+2}=4 a_{n+1}-4 a_{n}+n^{2}$ for $n \geq 2$. Compute the remainder obtained when $a_{2006}$ is divided by 100. | 0 | 0 |
Wesyu is a farmer, and she's building a cao (a relative of the cow) pasture. She starts with a triangle $A_{0} A_{1} A_{2}$ where angle $A_{0}$ is $90^{\circ}$, angle $A_{1}$ is $60^{\circ}$, and $A_{0} A_{1}$ is 1. She then extends the pasture. First, she extends $A_{2} A_{0}$ to $A_{3}$ such that $A_{3} A_{0}=\frac{1}{2} A_{2} A_{0}$ and the new pasture is triangle $A_{1} A_{2} A_{3}$. Next, she extends $A_{3} A_{1}$ to $A_{4}$ such that $A_{4} A_{1}=\frac{1}{6} A_{3} A_{1}$. She continues, each time extending $A_{n} A_{n-2}$ to $A_{n+1}$ such that $A_{n+1} A_{n-2}=\frac{1}{2^{n}-2} A_{n} A_{n-2}$. What is the smallest $K$ such that her pasture never exceeds an area of $K$? | \sqrt{3} | 0 |
A function $f: A \rightarrow A$ is called idempotent if $f(f(x))=f(x)$ for all $x \in A$. Let $I_{n}$ be the number of idempotent functions from $\{1,2, \ldots, n\}$ to itself. Compute $\sum_{n=1}^{\infty} \frac{I_{n}}{n!}$. | e^{e}-1 | 0 |
Determine all triplets of real numbers $(x, y, z)$ satisfying the system of equations $x^{2} y+y^{2} z =1040$, $x^{2} z+z^{2} y =260$, $(x-y)(y-z)(z-x) =-540$. | (16,4,1),(1,16,4) | 0 |
Subsets and Splits