lime-nlp/orz_math_difficulty · Datasets at Hugging Face

Unnamed: 0 int64 0 56.9k	problem stringlengths 16 7.44k	ground_truth stringlengths 1 942	solved_percentage float64 0 100
2,200	For a positive integer $n$ , let $I_n=\int_{-\pi}^{\pi} \left(\frac{\pi}{2}-\|x\|\right)\cos nx\ dx$ . Find $I_1+I_2+I_3+I_4$ . 1992 University of Fukui entrance exam/Medicine	\frac{40}{9}	35.15625
2,201	The diagram below is made up of a rectangle AGHB, an equilateral triangle AFG, a rectangle ADEF, and a parallelogram ABCD. Find the degree measure of ∠ABC. For diagram go to http://www.purplecomet.org/welcome/practice, the 2015 middle school contest, and go to #2	60^\circ	3.125
2,202	Determine the number of solutions of the simultaneous equations $ x^2 \plus{} y^3 \equal{} 29$ and $ \log_3 x \cdot \log_2 y \equal{} 1.$	2	16.40625
2,203	Let $f(x)$ be the polynomial $\prod_{k=1}^{50} \bigl( x - (2k-1) \bigr)$ . Let $c$ be the coefficient of $x^{48}$ in $f(x)$ . When $c$ is divided by 101, what is the remainder? (The remainder is an integer between 0 and 100.)	60	76.5625
2,204	Given a convex quadrilateral $ABCD$ in which $\angle BAC = 20^o$ , $\angle CAD = 60^o$ , $\angle ADB = 50^o$ , and $\angle BDC = 10^o$ . Find $\angle ACB$ .	80^\circ	0
2,205	How many real numbers are roots of the polynomial \[x^9 - 37x^8 - 2x^7 + 74x^6 + x^4 - 37x^3 - 2x^2 + 74x?\]	5	44.53125
2,206	Find all positive integers $n$ such that the product of all positive divisors of $n$ is $24^{240}$ .	n = 24^5	0
2,207	Let $h$ be a positive integer. The sequence $a_n$ is defined by $a_0 = 1$ and \[a_{n+1} = \{\begin{array}{c} \frac{a_n}{2} \text{ if } a_n \text{ is even }a_n+h \text{ otherwise }.\end{array}\] For example, $h = 27$ yields $a_1=28, a_2 = 14, a_3 = 7, a_4 = 34$ etc. For which $h$ is there an $n > 0$ with $a_n = 1$ ?	h	13.28125
2,208	Find the smallest positive integer $ n$ such that $ 107n$ has the same last two digits as $ n$ .	50	100
2,209	Let $\star$ be an operation defined in the set of nonnegative integers with the following properties: for any nonnegative integers $x$ and $y$ , (i) $(x + 1)\star 0 = (0\star x) + 1$ (ii) $0\star (y + 1) = (y\star 0) + 1$ (iii) $(x + 1)\star (y + 1) = (x\star y) + 1$ . If $123\star 456 = 789$ , find $246\star 135$ .	579	0
2,210	Let $\mathbb{Z}$ denote the set of all integers. Find all polynomials $P(x)$ with integer coefficients that satisfy the following property: For any infinite sequence $a_1$ , $a_2$ , $\dotsc$ of integers in which each integer in $\mathbb{Z}$ appears exactly once, there exist indices $i < j$ and an integer $k$ such that $a_i +a_{i+1} +\dotsb +a_j = P(k)$ .	P(x) = ax + b	6.25
2,211	In a $m\times n$ chessboard ( $m,n\ge 2$ ), some dominoes are placed (without overlap) with each domino covering exactly two adjacent cells. Show that if no more dominoes can be added to the grid, then at least $2/3$ of the chessboard is covered by dominoes. Proposed by DVDthe1st, mzy and jjax	\frac{2}{3}	96.875
2,212	Given a convex polygon M invariant under a $90^\circ$ rotation, show that there exist two circles, the ratio of whose radii is $\sqrt2$ , one containing M and the other contained in M. A. Khrabrov	\sqrt{2}	99.21875
2,213	p1. A fraction is called Toba- $n$ if the fraction has a numerator of $1$ and the denominator of $n$ . If $A$ is the sum of all the fractions of Toba- $101$ , Toba- $102$ , Toba- $103$ , to Toba- $200$ , show that $\frac{7}{12} <A <\frac56$ . p2. If $a, b$ , and $c$ satisfy the system of equations $$ \frac{ab}{a+b}=\frac12 $$ $$ \frac{bc}{b+c}=\frac13 $$ $$ \frac{ac}{a+c}=\frac17 $$ Determine the value of $(a- c)^b$ . p3. Given triangle $ABC$ . If point $M$ is located at the midpoint of $AC$ , point $N$ is located at the midpoint of $BC$ , and the point $P$ is any point on $AB$ . Determine the area of the quadrilateral $PMCN$ . ![Image](https://cdn.artofproblemsolving.com/attachments/4/d/175e2d55f889b9dd2d8f89b8bae6c986d87911.png) p4. Given the rule of motion of a particle on a flat plane $xy$ as following: $N: (m, n)\to (m + 1, n + 1)$ $T: (m, n)\to (m + 1, n - 1)$ , where $m$ and $n$ are integers. How many different tracks are there from $(0, 3)$ to $(7, 2)$ by using the above rules ? p5. Andra and Dedi played “SUPER-AS”. The rules of this game as following. Players take turns picking marbles from a can containing $30$ marbles. For each take, the player can take the least a minimum of $ 1$ and a maximum of $6$ marbles. The player who picks up the the last marbels is declared the winner. If Andra starts the game by taking $3$ marbles first, determine how many marbles should be taken by Dedi and what is the next strategy to take so that Dedi can be the winner.	6	10.15625
2,214	Let $ABC$ be an equilateral triangle of area $1998$ cm $^2$ . Points $K, L, M$ divide the segments $[AB], [BC] ,[CA]$ , respectively, in the ratio $3:4$ . Line $AL$ intersects the lines $CK$ and $BM$ respectively at the points $P$ and $Q$ , and the line $BM$ intersects the line $CK$ at point $R$ . Find the area of the triangle $PQR$ .	54 \, \text{cm}^2	0
2,215	There are 47 students in a classroom with seats arranged in 6 rows $ \times$ 8 columns, and the seat in the $ i$ -th row and $ j$ -th column is denoted by $ (i,j).$ Now, an adjustment is made for students’ seats in the new school term. For a student with the original seat $ (i,j),$ if his/her new seat is $ (m,n),$ we say that the student is moved by $ [a, b] \equal{} [i \minus{} m, j \minus{} n]$ and define the position value of the student as $ a\plus{}b.$ Let $ S$ denote the sum of the position values of all the students. Determine the difference between the greatest and smallest possible values of $ S.$	24	0.78125
2,216	Find all pairs of positive integers $m$ , $n$ such that the $(m+n)$ -digit number \[\underbrace{33\ldots3}_{m}\underbrace{66\ldots 6}_{n}\] is a perfect square.	(1, 1)	70.3125
2,217	Find the smallest constant $C > 1$ such that the following statement holds: for every integer $n \geq 2$ and sequence of non-integer positive real numbers $a_1, a_2, \dots, a_n$ satisfying $$ \frac{1}{a_1} + \frac{1}{a_2} + \cdots + \frac{1}{a_n} = 1, $$ it's possible to choose positive integers $b_i$ such that (i) for each $i = 1, 2, \dots, n$ , either $b_i = \lfloor a_i \rfloor$ or $b_i = \lfloor a_i \rfloor + 1$ , and (ii) we have $$ 1 < \frac{1}{b_1} + \frac{1}{b_2} + \cdots + \frac{1}{b_n} \leq C. $$ (Here $\lfloor \bullet \rfloor$ denotes the floor function, as usual.) Merlijn Staps	C = \frac{3}{2}	7.03125
2,218	An equilateral triangle with side length $6$ has a square of side length $6$ attached to each of its edges as shown. The distance between the two farthest vertices of this figure (marked $A$ and $B$ in the figure) can be written as $m + \sqrt{n}$ where $m$ and $n$ are positive integers. Find $m + n$ . [asy] draw((0,0)--(1,0)--(1/2,sqrt(3)/2)--cycle); draw((1,0)--(1+sqrt(3)/2,1/2)--(1/2+sqrt(3)/2,1/2+sqrt(3)/2)--(1/2,sqrt(3)/2)); draw((0,0)--(-sqrt(3)/2,1/2)--(-sqrt(3)/2+1/2,1/2+sqrt(3)/2)--(1/2,sqrt(3)/2)); dot((-sqrt(3)/2+1/2,1/2+sqrt(3)/2)); label("A", (-sqrt(3)/2+1/2,1/2+sqrt(3)/2), N); draw((1,0)--(1,-1)--(0,-1)--(0,0)); dot((1,-1)); label("B", (1,-1), SE); [/asy]	114	15.625
2,219	A regular $n$ -gon is inscribed in a unit circle. Compute the product from a fixed vertex to all the other vertices.	n	70.3125
2,220	A right triangle has perimeter $2008$ , and the area of a circle inscribed in the triangle is $100\pi^3$ . Let $A$ be the area of the triangle. Compute $\lfloor A\rfloor$ .	31541	50.78125
2,221	What is the sum of all primes $p$ such that $7^p - 6^p + 2$ is divisible by 43?	3	60.15625
2,222	Gage skated 1 hr 15 min each day for 5 days and 1 hr 30 min each day for 3 days. How long would he have to skate the ninth day in order to average 85 minutes of skating each day for the entire time? $\text{(A)}\ \text{1 hr} \qquad \text{(B)}\ \text{1 hr 10 min} \qquad \text{(C)}\ \text{1 hr 20 min} \qquad \text{(D)}\ \text{1 hr 40 min} \qquad \text{(E)}\ \text{2 hr}$	2 \text{ hr}	82.8125
2,223	Siva has the following expression, which is missing operations: $$ \frac12 \,\, \_ \,\,\frac14 \,\, \_ \,\, \frac18 \,\, \_ \,\,\frac{1}{16} \,\, \_ \,\,\frac{1}{32}. $$ For each blank, he flips a fair coin: if it comes up heads, he fills it with a plus, and if it comes up tails, he fills it with a minus. Afterwards, he computes the value of the expression. He then repeats the entire process with a new set of coinflips and operations. If the probability that the positive difference between his computed values is greater than $\frac12$ can be expressed as $\frac{a}{b}$ for relatively prime positive integers $a$ , $b$ , then find $a + b$ .	39	0
2,224	Use $ \log_{10} 2 \equal{} 0.301,\ \log_{10} 3 \equal{} 0.477,\ \log_{10} 7 \equal{} 0.845$ to find the value of $ \log_{10} (10!)$ . Note that you must answer according to the rules:fractional part of $ 0.5$ and higher is rounded up, and everything strictly less than $ 0.5$ is rounded down, say $ 1.234\longrightarrow 1.23$ . Then find the minimum integer value $ n$ such that $ 10! < 2^{n}$ .	22	58.59375
2,225	There are $2017$ turtles in a room. Every second, two turtles are chosen uniformly at random and combined to form one super-turtle. (Super-turtles are still turtles.) The probability that after $2015$ seconds (meaning when there are only two turtles remaining) there is some turtle that has never been combined with another turtle can be written in the form $\tfrac{p}{q}$ where $p$ and $q$ are relatively prime positive integers. Find $p + q$ .	1009	2.34375
2,226	For a finite graph $G$ , let $f(G)$ be the number of triangles and $g(G)$ the number of tetrahedra formed by edges of $G$ . Find the least constant $c$ such that \[g(G)^3\le c\cdot f(G)^4\] for every graph $G$ . Proposed by Marcin Kuczma, Poland	\frac{3}{32}	6.25
2,227	A rectangular piece of paper $ABCD$ has sides of lengths $AB = 1$ , $BC = 2$ . The rectangle is folded in half such that $AD$ coincides with $BC$ and $EF$ is the folding line. Then fold the paper along a line $BM$ such that the corner $A$ falls on line $EF$ . How large, in degrees, is $\angle ABM$ ? [asy] size(180); pathpen = rgb(0,0,0.6)+linewidth(1); pointpen = black+linewidth(3); pointfontpen = fontsize(10); pen dd = rgb(0,0,0.6) + linewidth(0.7) + linetype("4 4"), dr = rgb(0.8,0,0), dg = rgb(0,0.6,0), db = rgb(0,0,0.6)+linewidth(1); pair A=(0,1), B=(0,0), C=(2,0), D=(2,1), E=A/2, F=(2,.5), M=(1/3^.5,1), N=reflect(B,M)*A; D(B--M--D("N",N,NE)--B--D("C",C,SE)--D("D",D,NE)--M); D(D("M",M,plain.N)--D("A",A,NW)--D("B",B,SW),dd); D(D("E",E,W)--D("F",F,plain.E),dd); [/asy]	30^\circ	76.5625
2,228	The repeating decimals $0.abab\overline{ab}$ and $0.abcabc\overline{abc}$ satisfy \[0.abab\overline{ab}+0.abcabc\overline{abc}=\frac{33}{37},\] where $a,b$ , and $c$ are (not necessarily distinct) digits. Find the three-digit number $abc$ .	447	46.09375
2,229	Let $p$ be a prime number such that $p\equiv 1\pmod{4}$ . Determine $\sum_{k=1}^{\frac{p-1}{2}}\left \lbrace \frac{k^2}{p} \right \rbrace$ , where $\{x\}=x-[x]$ .	\frac{p-1}{4}	51.5625
2,230	In a finite sequence of real numbers the sum of any seven successive terms is negative and the sum of any eleven successive terms is positive. Determine the maximum number of terms in the sequence.	16	41.40625
2,231	Q. Find all polynomials $P: \mathbb{R \times R}\to\mathbb{R\times R}$ with real coefficients, such that $$ P(x,y) = P(x+y,x-y), \ \forall\ x,y \in \mathbb{R}. $$ Proposed by TuZo	P(x, y) = (a, b)	0
2,232	Let $X$ be a set with $n$ elements and $0 \le k \le n$ . Let $a_{n,k}$ be the maximum number of permutations of the set $X$ such that every two of them have at least $k$ common components (where a common component of $f$ and g is an $x \in X$ such that $f(x) = g(x)$ ). Let $b_{n,k}$ be the maximum number of permutations of the set $X$ such that every two of them have at most $k$ common components. (a) Show that $a_{n,k} \cdot b_{n,k-1} \le n!$ . (b) Let $p$ be prime, and find the exact value of $a_{p,2}$ .	(p-2)!	3.90625
2,233	Let $m$ and $n$ be positive integers such that $x=m+\sqrt{n}$ is a solution to the equation $x^2-10x+1=\sqrt{x}(x+1)$ . Find $m+n$ .	55	14.0625
2,234	In the plane there are $2020$ points, some of which are black and the rest are green. For every black point, the following applies: There are exactly two green points that represent the distance $2020$ from that black point. Find the smallest possible number of green dots. (Walther Janous)	45	0
2,235	Considering all numbers of the form $n = \lfloor \frac{k^3}{2012} \rfloor$ , where $\lfloor x \rfloor$ denotes the greatest integer less than or equal to $x$ , and $k$ ranges from $1$ to $2012$ , how many of these $n$ ’s are distinct?	1995	97.65625
2,236	A circle radius $320$ is tangent to the inside of a circle radius $1000$ . The smaller circle is tangent to a diameter of the larger circle at a point $P$ . How far is the point $P$ from the outside of the larger circle?	400	3.125
2,237	Find all positive integers $d$ for which there exist polynomials $P(x)$ and $Q(x)$ with real coefficients such that degree of $P$ equals $d$ and $$ P(x)^2+1=(x^2+1)Q(x)^2. $$	d	9.375
2,238	$ABCD$ is a cyclic quadrilateral inscribed in a circle of radius $5$ , with $AB=6$ , $BC=7$ , $CD=8$ . Find $AD$ .	\sqrt{51}	0
2,239	For every positive integer $k$ , let $\mathbf{T}_k = (k(k+1), 0)$ , and define $\mathcal{H}_k$ as the homothety centered at $\mathbf{T}_k$ with ratio $\tfrac{1}{2}$ if $k$ is odd and $\tfrac{2}{3}$ is $k$ is even. Suppose $P = (x,y)$ is a point such that $$ (\mathcal{H}_{4} \circ \mathcal{H}_{3} \circ \mathcal{H}_2 \circ \mathcal{H}_1)(P) = (20, 20). $$ What is $x+y$ ? (A homothety $\mathcal{H}$ with nonzero ratio $r$ centered at a point $P$ maps each point $X$ to the point $Y$ on ray $\overrightarrow{PX}$ such that $PY = rPX$ .)	256	17.1875
2,240	Find the total number of solutions to the following system of equations: \[ \begin{cases} a^2\plus{}bc\equiv a\pmod {37} b(a\plus{}d)\equiv b\pmod {37} c(a\plus{}d)\equiv c\pmod{37} bc\plus{}d^2\equiv d\pmod{37} ad\minus{}bc\equiv 1\pmod{37}\end{cases}\]	1	19.53125
2,241	Triangle $ABC$ is right angled at $A$ . The circle with center $A$ and radius $AB$ cuts $BC$ and $AC$ internally at $D$ and $E$ respectively. If $BD = 20$ and $DC = 16$ , determine $AC^2$ .	936	3.125
2,242	Let the three sides of a triangle be $\ell, m, n$ , respectively, satisfying $\ell>m>n$ and $\left\{\frac{3^\ell}{10^4}\right\}=\left\{\frac{3^m}{10^4}\right\}=\left\{\frac{3^n}{10^4}\right\}$ , where $\{x\}=x-\lfloor{x}\rfloor$ and $\lfloor{x}\rfloor$ denotes the integral part of the number $x$ . Find the minimum perimeter of such a triangle.	3003	2.34375
2,243	Let $m$ be a positive integer, and let $a_0, a_1,\ldots,a_m$ be a sequence of reals such that $a_0=37$ , $a_1=72$ , $a_m=0$ , and \[a_{k+1}=a_{k-1}-\frac{3}{a_k}\] for $k=1,2, \dots, m-1$ . Find $m$ .	889	97.65625
2,244	The isoelectric point of glycine is the pH at which it has zero charge. Its charge is $-\frac13$ at pH $3.55$ , while its charge is $\frac12$ at pH $9.6$ . Charge increases linearly with pH. What is the isoelectric point of glycine?	5.97	43.75
2,245	There are two round tables with $n{}$ dwarves sitting at each table. Each dwarf has only two friends: his neighbours to the left and to the right. A good wizard wants to seat the dwarves at one round table so that each two neighbours are friends. His magic allows him to make any $2n$ pairs of dwarves into pairs of friends (the dwarves in a pair may be from the same or from different tables). However, he knows that an evil sorcerer will break $n{}$ of those new friendships. For which $n{}$ is the good wizard able to achieve his goal no matter what the evil sorcerer does? Mikhail Svyatlovskiy	n	64.0625
2,246	Find all functions $f$ from the reals into the reals such that \[ f(ab) = f(a+b) \] for all irrational $a, b$ .	f(x) = c	67.96875
2,247	For a positive integer $n$ , there is a school with $2n$ people. For a set $X$ of students in this school, if any two students in $X$ know each other, we call $X$ well-formed. If the maximum number of students in a well-formed set is no more than $n$ , find the maximum number of well-formed set. Here, an empty set and a set with one student is regarded as well-formed as well.	3^n	0
2,248	The intersection of two squares with perimeter $8$ is a rectangle with diagonal length $1$ . Given that the distance between the centers of the two squares is $2$ , the perimeter of the rectangle can be expressed as $P$ . Find $10P$ .	25	7.03125
2,249	In a competition there are $18$ teams and in each round $18$ teams are divided into $9$ pairs where the $9$ matches are played coincidentally. There are $17$ rounds, so that each pair of teams play each other exactly once. After $n$ rounds, there always exists $4$ teams such that there was exactly one match played between these teams in those $n$ rounds. Find the maximum value of $n$ .	7	10.9375
2,250	In a room there are $144$ people. They are joined by $n$ other people who are each carrying $k$ coins. When these coins are shared among all $n + 144$ people, each person has $2$ of these coins. Find the minimum possible value of $2n + k$ .	50	93.75
2,251	Point D is from AC of triangle ABC so that 2AD=DC. Let DE be perpendicular to BC and AE intersects BD at F. It is known that triangle BEF is equilateral. Find <ADB?	90^\circ	21.875
2,252	Let $S_n$ be the sum of the reciprocals of the non-zero digits of the integers from 1 to $10^n$ inclusive. Find the smallest positive integer $n$ for which $S_n$ is an integer.	63	65.625
2,253	A terrain ( $ABCD$ ) has a rectangular trapezoidal shape. The angle in $A$ measures $90^o$ . $AB$ measures $30$ m, $AD$ measures $20$ m and $DC$ measures 45 m. This land must be divided into two areas of the same area, drawing a parallel to the $AD$ side . At what distance from $D$ do we have to draw the parallel? ![Image](https://1.bp.blogspot.com/-DnyNY3x4XKE/XNYvRUrLVTI/AAAAAAAAKLE/gohd7_S9OeIi-CVUVw-iM63uXE5u-WmGwCK4BGAYYCw/s400/image002.gif)	18.75 \text{ m}	0.78125
2,254	For the NEMO, Kevin needs to compute the product \[ 9 \times 99 \times 999 \times \cdots \times 999999999. \] Kevin takes exactly $ab$ seconds to multiply an $a$ -digit integer by a $b$ -digit integer. Compute the minimum number of seconds necessary for Kevin to evaluate the expression together by performing eight such multiplications. Proposed by Evan Chen	870	27.34375
2,255	We define the function $f(x,y)=x^3+(y-4)x^2+(y^2-4y+4)x+(y^3-4y^2+4y)$ . Then choose any distinct $a, b, c \in \mathbb{R}$ such that the following holds: $f(a,b)=f(b,c)=f(c,a)$ . Over all such choices of $a, b, c$ , what is the maximum value achieved by \[\min(a^4 - 4a^3 + 4a^2, b^4 - 4b^3 + 4b^2, c^4 - 4c^3 + 4c^2)?\]	1	14.84375
2,256	A sequence of vertices $v_1,v_2,\ldots,v_k$ in a graph, where $v_i=v_j$ only if $i=j$ and $k$ can be any positive integer, is called a $\textit{cycle}$ if $v_1$ is attached by an edge to $v_2$ , $v_2$ to $v_3$ , and so on to $v_k$ connected to $v_1$ . Rotations and reflections are distinct: $A,B,C$ is distinct from $A,C,B$ and $B,C,A$ . Supposed a simple graph $G$ has $2013$ vertices and $3013$ edges. What is the minimal number of cycles possible in $G$ ?	1001	94.53125
2,257	Gus has to make a list of $250$ positive integers, not necessarily distinct, such that each number is equal to the number of numbers in the list that are different from it. For example, if $15$ is a number from the list so the list contains $15$ numbers other than $15$ . Determine the maximum number of distinct numbers the Gus list can contain.	21	8.59375
2,258	At a certain grocery store, cookies may be bought in boxes of $10$ or $21.$ What is the minimum positive number of cookies that must be bought so that the cookies may be split evenly among $13$ people? Author: Ray Li	52	92.1875
2,259	An infinite sheet of paper is divided into equal squares, some of which are colored red. In each $2\times3$ rectangle, there are exactly two red squares. Now consider an arbitrary $9\times11$ rectangle. How many red squares does it contain? (The sides of all considered rectangles go along the grid lines.)	33	50.78125
2,260	Find all functions $f:\mathbb{N} \to \mathbb{N}$ such that for all $m,n\in \mathbb{N}$ : - $f(2)=2$ , - $f(mn)=f(m)f(n)$ , - $f(n+1)>f(n)$ .	f(n) = n	100
2,261	Define the hotel elevator cubicas the unique cubic polynomial $P$ for which $P(11) = 11$ , $P(12) = 12$ , $P(13) = 14$ , $P(14) = 15$ . What is $P(15)$ ? Proposed by Evan Chen	13	68.75
2,262	Four positive integers $a, b, c, d$ satisfy the condition: $a < b < c < d$ . For what smallest possible value of $d$ could the following condition be true: the arithmetic mean of numbers $a, b, c$ is twice smaller than the arithmetic mean of numbers $a, b, c, d$ ?	10	83.59375
2,263	Find all real numbers $x$ that satisfy the equation $$ \frac{x-2020}{1}+\frac{x-2019}{2}+\cdots+\frac{x-2000}{21}=\frac{x-1}{2020}+\frac{x-2}{2019}+\cdots+\frac{x-21}{2000}, $$ and simplify your answer(s) as much as possible. Justify your solution.	x = 2021	67.1875
2,264	A quadratic polynomial $p(x)$ with integer coefficients satisfies $p(41) = 42$ . For some integers $a, b > 41$ , $p(a) = 13$ and $p(b) = 73$ . Compute the value of $p(1)$ . Proposed by Aaron Lin	2842	4.6875
2,265	The polynomial $P$ is a quadratic with integer coefficients. For every positive integer $n$ , the integers $P(n)$ and $P(P(n))$ are relatively prime to $n$ . If $P(3) = 89$ , what is the value of $P(10)$ ?	859	0
2,266	Let $k$ be a real number such that the product of real roots of the equation $$ X^4 + 2X^3 + (2 + 2k)X^2 + (1 + 2k)X + 2k = 0 $$ is $-2013$ . Find the sum of the squares of these real roots.	4027	9.375
2,267	Find all natural numbers $n> 1$ for which the following applies: The sum of the number $n$ and its second largest divisor is $2013$ . (R. Henner, Vienna)	n = 1342	0
2,268	A student did not notice multiplication sign between two three-digit numbers and wrote it as a six-digit number. Result was 7 times more that it should be. Find these numbers. (2 points)	(143, 143)	0.78125
2,269	Suppose that each of $n$ people knows exactly one piece of information and all $n$ pieces are different. Every time person $A$ phones person $B$ , $A$ tells $B$ everything he knows, while tells $A$ nothing. What is the minimum of phone calls between pairs of people needed for everyone to know everything?	2n - 2	5.46875
2,270	Let $ S(n) $ be the sum of the squares of the positive integers less than and coprime to $ n $ . For example, $ S(5) = 1^2 + 2^2 + 3^2 + 4^2 $ , but $ S(4) = 1^2 + 3^2 $ . Let $ p = 2^7 - 1 = 127 $ and $ q = 2^5 - 1 = 31 $ be primes. The quantity $ S(pq) $ can be written in the form $$ \frac{p^2q^2}{6}\left(a - \frac{b}{c} \right) $$ where $ a $ , $ b $ , and $ c $ are positive integers, with $ b $ and $ c $ coprime and $ b < c $ . Find $ a $ .	7561	0.78125
2,271	When a function $f(x)$ is differentiated $n$ times ,the function we get id denoted $f^n(x)$ .If $f(x)=\dfrac {e^x}{x}$ .Find the value of \[\lim_{n \to \infty} \dfrac {f^ {2n}(1)}{(2n)!}\]	1	16.40625
2,272	Determine the smallest integer $k > 1$ such that there exist $k$ distinct primes whose squares sum to a power of $2$ .	k = 5	0
2,273	Region $ABCDEFGHIJ$ consists of $13$ equal squares and is inscribed in rectangle $PQRS$ with $A$ on $\overline{PQ}$ , $B$ on $\overline{QR}$ , $E$ on $\overline{RS}$ , and $H$ on $\overline{SP}$ , as shown in the figure on the right. Given that $PQ=28$ and $QR=26$ , determine, with proof, the area of region $ABCDEFGHIJ$ . [asy] size(200); defaultpen(linewidth(0.7)+fontsize(12)); pair P=(0,0), Q=(0,28), R=(26,28), S=(26,0), B=(3,28); draw(P--Q--R--S--cycle); picture p = new picture; draw(p, (0,0)--(3,0)^^(0,-1)--(3,-1)^^(0,-2)--(5,-2)^^(0,-3)--(5,-3)^^(2,-4)--(3,-4)^^(2,-5)--(3,-5)); draw(p, (0,0)--(0,-3)^^(1,0)--(1,-3)^^(2,0)--(2,-5)^^(3,0)--(3,-5)^^(4,-2)--(4,-3)^^(5,-2)--(5,-3)); transform t = shift(B) * rotate(-aSin(1/26^.5)) * scale(26^.5); add(tp); label(" $P$ ",P,SW); label(" $Q$ ",Q,NW); label(" $R$ ",R,NE); label(" $S$ ",S,SE); label(" $A$ ",t(0,-3),W); label(" $B$ ",B,N); label(" $C$ ",t(3,0),plain.ENE); label(" $D$ ",t(3,-2),NE); label(" $E$ ",t(5,-2),plain.E); label(" $F$ ",t(5,-3),plain.SW); label(" $G$ ",t(3,-3),(0.81,-1.3)); label(" $H$ ",t(3,-5),plain.S); label(" $I$ ",t(2,-5),NW); label(" $J$ ",t(2,-3),SW);[/asy]	338	0.78125
2,274	Let $S$ be the sum of the base 10 logarithms of all the proper divisors of 1000000. What is the integer nearest to $S$ ?	141	62.5
2,275	Two players play a game on a pile of $n$ beans. On each player's turn, they may take exactly $1$ , $4$ , or $7$ beans from the pile. One player goes first, and then the players alternate until somebody wins. A player wins when they take the last bean from the pile. For how many $n$ between $2014$ and $2050$ (inclusive) does the second player win?	14	91.40625
2,276	Q11. Let be given a sequense $a_1=5, \; a_2=8$ and $a_{n+1}=a_n+3a_{n-1}, \qquad n=1,2,3,...$ Calculate the greatest common divisor of $a_{2011}$ and $a_{2012}$ .	1	5.46875
2,277	It is given that there exists a unique triple of positive primes $(p,q,r)$ such that $p<q<r$ and \[\dfrac{p^3+q^3+r^3}{p+q+r} = 249.\] Find $r$ .	r = 19	0
2,278	Let $p$ prime and $m$ a positive integer. Determine all pairs $( p,m)$ satisfying the equation: $ p(p+m)+p=(m+1)^3$	(2, 1)	18.75
2,279	$p(x)$ is the cubic $x^3 - 3x^2 + 5x$ . If $h$ is a real root of $p(x) = 1$ and $k$ is a real root of $p(x) = 5$ , find $h + k$ .	h + k = 2	0
2,280	A crazy physicist has discovered a new particle called an omon. He has a machine, which takes two omons of mass $a$ and $b$ and entangles them; this process destroys the omon with mass $a$ , preserves the one with mass $b$ , and creates a new omon whose mass is $\frac 12 (a+b)$ . The physicist can then repeat the process with the two resulting omons, choosing which omon to destroy at every step. The physicist initially has two omons whose masses are distinct positive integers less than $1000$ . What is the maximum possible number of times he can use his machine without producing an omon whose mass is not an integer? Proposed by Michael Kural	9	85.15625
2,281	A mustache is created by taking the set of points $(x, y)$ in the $xy$ -coordinate plane that satisfy $4 + 4 \cos(\pi x/24) \le y \le 6 + 6\cos(\pi x/24)$ and $-24 \le x \le 24$ . What is the area of the mustache?	96	96.09375
2,282	Let $\{a_n\}_{n=1}^{\infty}$ and $\{b_n\}_{n=1}^{\infty}$ be sequences of integers such that $a_1 = 20$ , $b_1 = 15$ , and for $n \ge 1$ , \[\left\{\begin{aligned} a_{n+1}&=a_n^2-b_n^2, b_{n+1}&=2a_nb_n-b_n^2 \end{aligned}\right.\] Let $G = a_{10}^2-a_{10}b_{10}+b_{10}^2$ . Determine the number of positive integer factors of $G$ . Proposed by Michael Ren	525825	0
2,283	Let $ n\geq 3 $ be an integer and let $ x_1,x_2,\ldots,x_{n-1} $ be nonnegative integers such that \begin{eqnarray} \ x_1 + x_2 + \cdots + x_{n-1} &=& n x_1 + 2x_2 + \cdots + (n-1)x_{n-1} &=& 2n-2. \end{eqnarray} Find the minimal value of $ F(x_1,x_2,\ldots,x_n) = \sum_{k=1}^{n-1} k(2n-k)x_k $ .	3n(n-1)	3.90625
2,284	Let $a_1, a_2, a_3, a_4$ be integers with distinct absolute values. In the coordinate plane, let $A_1=(a_1,a_1^2)$ , $A_2=(a_2,a_2^2)$ , $A_3=(a_3,a_3^2)$ and $A_4=(a_4,a_4^2)$ . Assume that lines $A_1A_2$ and $A_3A_4$ intersect on the $y$ -axis at an acute angle of $\theta$ . The maximum possible value for $\tan \theta$ can be expressed in the form $\dfrac mn$ for relatively prime positive integers $m$ and $n$ . Find $100m+n$ . Proposed by James Lin	503	0
2,285	Consider the sequence $$ 1,7,8,49,50,56,57,343\ldots $$ which consists of sums of distinct powers of $7$ , that is, $7^0$ , $7^1$ , $7^0+7^1$ , $7^2$ , $\ldots$ in increasing order. At what position will $16856$ occur in this sequence?	36	10.15625
2,286	Compute the maximum integer value of $k$ such that $2^k$ divides $3^{2n+3}+40n-27$ for any positive integer $n$ .	6	20.3125
2,287	Find the greatest positive real number $M$ such that for all positive real sequence $(a_n)$ and for all real number $m < M$ , it is possible to find some index $n \ge 1$ that satisfies the inequality $a_1 + a_2 + a_3 + ...+ a_n +a_{n+1} > m a_n$ .	M = 4	0
2,288	Find the number of pairs of positive integers $a$ and $b$ such that $a\leq 100\,000$ , $b\leq 100\,000$ , and $$ \frac{a^3-b}{a^3+b}=\frac{b^2-a^2}{b^2+a^2}. $$	10	46.875
2,289	Suppose that $m$ and $n$ are relatively prime positive integers with $A = \tfrac mn$ , where \[ A = \frac{2+4+6+\dots+2014}{1+3+5+\dots+2013} - \frac{1+3+5+\dots+2013}{2+4+6+\dots+2014}. \] Find $m$ . In other words, find the numerator of $A$ when $A$ is written as a fraction in simplest form. Proposed by Evan Chen	2015	85.15625
2,290	Each person stands on a whole number on the number line from $0$ to $2022$ . In each turn, two people are selected by a distance of at least $2$ . These go towards each other by $1$ . When no more such moves are possible, the process ends. Show that this process always ends after a finite number of moves, and determine all possible configurations where people can end up standing. (whereby is for each configuration is only of interest how many people stand at each number.) (Birgit Vera Schmidt) <details><summary>original wording</summary>Bei jeder ganzen Zahl auf dem Zahlenstrahl von 0 bis 2022 steht zu Beginn eine Person. In jedem Zug werden zwei Personen mit Abstand mindestens 2 ausgewählt. Diese gehen jeweils um 1 aufeinander zu. Wenn kein solcher Zug mehr möglich ist, endet der Vorgang. Man zeige, dass dieser Vorgang immer nach endlich vielen Zügen endet, und bestimme alle möglichen Konfigurationen, wo die Personen am Ende stehen können. (Dabei ist für jede Konfiguration nur von Interesse, wie viele Personen bei jeder Zahl stehen.)</details>	1011	1.5625
2,291	A sequence $a_1, a_2, \ldots$ satisfies $a_1 = \dfrac 52$ and $a_{n + 1} = {a_n}^2 - 2$ for all $n \ge 1.$ Let $M$ be the integer which is closest to $a_{2023}.$ The last digit of $M$ equals $$ \mathrm a. ~ 0\qquad \mathrm b.~2\qquad \mathrm c. ~4 \qquad \mathrm d. ~6 \qquad \mathrm e. ~8 $$	4	3.90625
2,292	Which number is greater: $$ A=\frac{2.00\ldots04}{1.00\ldots04^2+2.00\ldots04},\text{ or }B=\frac{2.00\ldots02}{1.00\ldots02^2+2.00\ldots02}, $$ where each of the numbers above contains $1998$ zeros?	B	69.53125
2,293	The target below is made up of concentric circles with diameters $4$ , $8$ , $12$ , $16$ , and $20$ . The area of the dark region is $n\pi$ . Find $n$ . [asy] size(150); defaultpen(linewidth(0.8)); int i; for(i=5;i>=1;i=i-1) { if (floor(i/2)==i/2) { filldraw(circle(origin,4i),white); } else { filldraw(circle(origin,4i),red); } } [/asy]	60	34.375
2,294	In circle $\Omega$ , let $\overline{AB}=65$ be the diameter and let points $C$ and $D$ lie on the same side of arc $\overarc{AB}$ such that $CD=16$ , with $C$ closer to $B$ and $D$ closer to $A$ . Moreover, let $AD, BC, AC,$ and $BD$ all have integer lengths. Two other circles, circles $\omega_1$ and $\omega_2$ , have $\overline{AC}$ and $\overline{BD}$ as their diameters, respectively. Let circle $\omega_1$ intersect $AB$ at a point $E \neq A$ and let circle $\omega_2$ intersect $AB$ at a point $F \neq B$ . Then $EF=\frac{m}{n}$ , for relatively prime integers $m$ and $n$ . Find $m+n$ . [asy] size(7cm); pair A=(0,0), B=(65,0), C=(117/5,156/5), D=(125/13,300/13), E=(23.4,0), F=(9.615,0); draw(A--B--C--D--cycle); draw(A--C); draw(B--D); dot(" $A$ ", A, SW); dot(" $B$ ", B, SE); dot(" $C$ ", C, NE); dot(" $D$ ", D, NW); dot(" $E$ ", E, S); dot(" $F$ ", F, S); draw(circle((A + C)/2, abs(A - C)/2)); draw(circle((B + D)/2, abs(B - D)/2)); draw(circle((A + B)/2, abs(A - B)/2)); label(" $\mathcal P$ ", (A + B)/2 + abs(A - B)/2 * dir(-45), dir(-45)); label(" $\mathcal Q$ ", (A + C)/2 + abs(A - C)/2 * dir(-210), dir(-210)); label(" $\mathcal R$ ", (B + D)/2 + abs(B - D)/2 * dir(70), dir(70)); [/asy] Proposed by AOPS12142015**	961	0
2,295	Let $ABCD$ be a square, and let $M$ be the midpoint of side $BC$ . Points $P$ and $Q$ lie on segment $AM$ such that $\angle BPD=\angle BQD=135^\circ$ . Given that $AP<AQ$ , compute $\tfrac{AQ}{AP}$ .	\sqrt{5}	0.78125
2,296	Starting from 37, adding 5 before each previous term, forms the following sequence: \[37,537,5537,55537,555537,...\] How many prime numbers are there in this sequence?	1	91.40625
2,297	Let $f(t)$ be the cubic polynomial for $t$ such that $\cos 3x=f(\cos x)$ holds for all real number $x$ . Evaluate \[\int_0^1 \{f(t)\}^2 \sqrt{1-t^2}dt\]	\frac{\pi}{8}	39.84375
2,298	Ana has $22$ coins. She can take from her friends either $6$ coins or $18$ coins, or she can give $12$ coins to her friends. She can do these operations many times she wants. Find the least number of coins Ana can have.	4	83.59375
2,299	Find the least $k$ for which the number $2010$ can be expressed as the sum of the squares of $k$ integers.	k=3	36.71875

2,200

For a positive integer $n$ , let $I_n=\int_{-\pi}^{\pi} \left(\frac{\pi}{2}-|x|\right)\cos nx\ dx$ . Find $I_1+I_2+I_3+I_4$ . *1992 University of Fukui entrance exam/Medicine*

\frac{40}{9}

35.15625

2,201

The diagram below is made up of a rectangle AGHB, an equilateral triangle AFG, a rectangle ADEF, and a parallelogram ABCD. Find the degree measure of ∠ABC. For diagram go to http://www.purplecomet.org/welcome/practice, the 2015 middle school contest, and go to #2

60^\circ

3.125

2,202

Determine the number of solutions of the simultaneous equations $ x^2 \plus{} y^3 \equal{} 29$ and $ \log_3 x \cdot \log_2 y \equal{} 1.$

2

16.40625

2,203

Let $f(x)$ be the polynomial $\prod_{k=1}^{50} \bigl( x - (2k-1) \bigr)$ . Let $c$ be the coefficient of $x^{48}$ in $f(x)$ . When $c$ is divided by 101, what is the remainder? (The remainder is an integer between 0 and 100.)

60

76.5625

2,204

Given a convex quadrilateral $ABCD$ in which $\angle BAC = 20^o$ , $\angle CAD = 60^o$ , $\angle ADB = 50^o$ , and $\angle BDC = 10^o$ . Find $\angle ACB$ .

80^\circ

0

2,205

How many real numbers are roots of the polynomial \[x^9 - 37x^8 - 2x^7 + 74x^6 + x^4 - 37x^3 - 2x^2 + 74x?\]

5

44.53125

2,206

Find all positive integers $n$ such that the product of all positive divisors of $n$ is $24^{240}$ .

n = 24^5

0

2,207

Let $h$ be a positive integer. The sequence $a_n$ is defined by $a_0 = 1$ and \[a_{n+1} = \{\begin{array}{c} \frac{a_n}{2} \text{ if } a_n \text{ is even }a_n+h \text{ otherwise }.\end{array}\] For example, $h = 27$ yields $a_1=28, a_2 = 14, a_3 = 7, a_4 = 34$ etc. For which $h$ is there an $n > 0$ with $a_n = 1$ ?

h

13.28125

2,208

Find the smallest positive integer $ n$ such that $ 107n$ has the same last two digits as $ n$ .

50

100

2,209

Let $\star$ be an operation defined in the set of nonnegative integers with the following properties: for any nonnegative integers $x$ and $y$ , (i) $(x + 1)\star 0 = (0\star x) + 1$ (ii) $0\star (y + 1) = (y\star 0) + 1$ (iii) $(x + 1)\star (y + 1) = (x\star y) + 1$ . If $123\star 456 = 789$ , find $246\star 135$ .

579

0

2,210

Let $\mathbb{Z}$ denote the set of all integers. Find all polynomials $P(x)$ with integer coefficients that satisfy the following property: For any infinite sequence $a_1$ , $a_2$ , $\dotsc$ of integers in which each integer in $\mathbb{Z}$ appears exactly once, there exist indices $i < j$ and an integer $k$ such that $a_i +a_{i+1} +\dotsb +a_j = P(k)$ .

P(x) = ax + b

6.25

2,211

In a $m\times n$ chessboard ( $m,n\ge 2$ ), some dominoes are placed (without overlap) with each domino covering exactly two adjacent cells. Show that if no more dominoes can be added to the grid, then at least $2/3$ of the chessboard is covered by dominoes. *Proposed by DVDthe1st, mzy and jjax*

\frac{2}{3}

96.875

2,212

Given a convex polygon M invariant under a $90^\circ$ rotation, show that there exist two circles, the ratio of whose radii is $\sqrt2$ , one containing M and the other contained in M. *A. Khrabrov*

\sqrt{2}

99.21875

2,213

p1. A fraction is called Toba- $n$ if the fraction has a numerator of $1$ and the denominator of $n$ . If $A$ is the sum of all the fractions of Toba- $101$ , Toba- $102$ , Toba- $103$ , to Toba- $200$ , show that $\frac{7}{12} <A <\frac56$ . p2. If $a, b$ , and $c$ satisfy the system of equations $$ \frac{ab}{a+b}=\frac12 $$ $$ \frac{bc}{b+c}=\frac13 $$ $$ \frac{ac}{a+c}=\frac17 $$ Determine the value of $(a- c)^b$ . p3. Given triangle $ABC$ . If point $M$ is located at the midpoint of $AC$ , point $N$ is located at the midpoint of $BC$ , and the point $P$ is any point on $AB$ . Determine the area of the quadrilateral $PMCN$ . ![Image](https://cdn.artofproblemsolving.com/attachments/4/d/175e2d55f889b9dd2d8f89b8bae6c986d87911.png) p4. Given the rule of motion of a particle on a flat plane $xy$ as following: $N: (m, n)\to (m + 1, n + 1)$ $T: (m, n)\to (m + 1, n - 1)$ , where $m$ and $n$ are integers. How many different tracks are there from $(0, 3)$ to $(7, 2)$ by using the above rules ? p5. Andra and Dedi played “SUPER-AS”. The rules of this game as following. Players take turns picking marbles from a can containing $30$ marbles. For each take, the player can take the least a minimum of $ 1$ and a maximum of $6$ marbles. The player who picks up the the last marbels is declared the winner. If Andra starts the game by taking $3$ marbles first, determine how many marbles should be taken by Dedi and what is the next strategy to take so that Dedi can be the winner.

6

10.15625

2,214

Let $ABC$ be an equilateral triangle of area $1998$ cm $^2$ . Points $K, L, M$ divide the segments $[AB], [BC] ,[CA]$ , respectively, in the ratio $3:4$ . Line $AL$ intersects the lines $CK$ and $BM$ respectively at the points $P$ and $Q$ , and the line $BM$ intersects the line $CK$ at point $R$ . Find the area of the triangle $PQR$ .

54 \, \text{cm}^2

0

2,215

There are 47 students in a classroom with seats arranged in 6 rows $ \times$ 8 columns, and the seat in the $ i$ -th row and $ j$ -th column is denoted by $ (i,j).$ Now, an adjustment is made for students’ seats in the new school term. For a student with the original seat $ (i,j),$ if his/her new seat is $ (m,n),$ we say that the student is moved by $ [a, b] \equal{} [i \minus{} m, j \minus{} n]$ and define the position value of the student as $ a\plus{}b.$ Let $ S$ denote the sum of the position values of all the students. Determine the difference between the greatest and smallest possible values of $ S.$

24

0.78125

2,216

Find all pairs of positive integers $m$ , $n$ such that the $(m+n)$ -digit number \[\underbrace{33\ldots3}_{m}\underbrace{66\ldots 6}_{n}\] is a perfect square.

(1, 1)

70.3125

2,217

Find the smallest constant $C > 1$ such that the following statement holds: for every integer $n \geq 2$ and sequence of non-integer positive real numbers $a_1, a_2, \dots, a_n$ satisfying $$ \frac{1}{a_1} + \frac{1}{a_2} + \cdots + \frac{1}{a_n} = 1, $$ it's possible to choose positive integers $b_i$ such that (i) for each $i = 1, 2, \dots, n$ , either $b_i = \lfloor a_i \rfloor$ or $b_i = \lfloor a_i \rfloor + 1$ , and (ii) we have $$ 1 < \frac{1}{b_1} + \frac{1}{b_2} + \cdots + \frac{1}{b_n} \leq C. $$ (Here $\lfloor \bullet \rfloor$ denotes the floor function, as usual.) *Merlijn Staps*

C = \frac{3}{2}

7.03125

2,218

An equilateral triangle with side length $6$ has a square of side length $6$ attached to each of its edges as shown. The distance between the two farthest vertices of this figure (marked $A$ and $B$ in the figure) can be written as $m + \sqrt{n}$ where $m$ and $n$ are positive integers. Find $m + n$ . [asy] draw((0,0)--(1,0)--(1/2,sqrt(3)/2)--cycle); draw((1,0)--(1+sqrt(3)/2,1/2)--(1/2+sqrt(3)/2,1/2+sqrt(3)/2)--(1/2,sqrt(3)/2)); draw((0,0)--(-sqrt(3)/2,1/2)--(-sqrt(3)/2+1/2,1/2+sqrt(3)/2)--(1/2,sqrt(3)/2)); dot((-sqrt(3)/2+1/2,1/2+sqrt(3)/2)); label("A", (-sqrt(3)/2+1/2,1/2+sqrt(3)/2), N); draw((1,0)--(1,-1)--(0,-1)--(0,0)); dot((1,-1)); label("B", (1,-1), SE); [/asy]

114

15.625

2,219

A regular $n$ -gon is inscribed in a unit circle. Compute the product from a fixed vertex to all the other vertices.

n

70.3125

2,220

A right triangle has perimeter $2008$ , and the area of a circle inscribed in the triangle is $100\pi^3$ . Let $A$ be the area of the triangle. Compute $\lfloor A\rfloor$ .

31541

50.78125

2,221

What is the sum of all primes $p$ such that $7^p - 6^p + 2$ is divisible by 43?

3

60.15625

2,222

Gage skated 1 hr 15 min each day for 5 days and 1 hr 30 min each day for 3 days. How long would he have to skate the ninth day in order to average 85 minutes of skating each day for the entire time? $\text{(A)}\ \text{1 hr} \qquad \text{(B)}\ \text{1 hr 10 min} \qquad \text{(C)}\ \text{1 hr 20 min} \qquad \text{(D)}\ \text{1 hr 40 min} \qquad \text{(E)}\ \text{2 hr}$

2 \text{ hr}

82.8125

2,223

Siva has the following expression, which is missing operations: $$ \frac12 \,\, \_ \,\,\frac14 \,\, \_ \,\, \frac18 \,\, \_ \,\,\frac{1}{16} \,\, \_ \,\,\frac{1}{32}. $$ For each blank, he flips a fair coin: if it comes up heads, he fills it with a plus, and if it comes up tails, he fills it with a minus. Afterwards, he computes the value of the expression. He then repeats the entire process with a new set of coinflips and operations. If the probability that the positive difference between his computed values is greater than $\frac12$ can be expressed as $\frac{a}{b}$ for relatively prime positive integers $a$ , $b$ , then find $a + b$ .

39

0

2,224

Use $ \log_{10} 2 \equal{} 0.301,\ \log_{10} 3 \equal{} 0.477,\ \log_{10} 7 \equal{} 0.845$ to find the value of $ \log_{10} (10!)$ . Note that you must answer according to the rules:fractional part of $ 0.5$ and higher is rounded up, and everything strictly less than $ 0.5$ is rounded down, say $ 1.234\longrightarrow 1.23$ . Then find the minimum integer value $ n$ such that $ 10! < 2^{n}$ .

22

58.59375

2,225

There are $2017$ turtles in a room. Every second, two turtles are chosen uniformly at random and combined to form one super-turtle. (Super-turtles are still turtles.) The probability that after $2015$ seconds (meaning when there are only two turtles remaining) there is some turtle that has never been combined with another turtle can be written in the form $\tfrac{p}{q}$ where $p$ and $q$ are relatively prime positive integers. Find $p + q$ .

1009

2.34375

2,226

For a finite graph $G$ , let $f(G)$ be the number of triangles and $g(G)$ the number of tetrahedra formed by edges of $G$ . Find the least constant $c$ such that \[g(G)^3\le c\cdot f(G)^4\] for every graph $G$ . *Proposed by Marcin Kuczma, Poland*

\frac{3}{32}

6.25

2,227

A rectangular piece of paper $ABCD$ has sides of lengths $AB = 1$ , $BC = 2$ . The rectangle is folded in half such that $AD$ coincides with $BC$ and $EF$ is the folding line. Then fold the paper along a line $BM$ such that the corner $A$ falls on line $EF$ . How large, in degrees, is $\angle ABM$ ? [asy] size(180); pathpen = rgb(0,0,0.6)+linewidth(1); pointpen = black+linewidth(3); pointfontpen = fontsize(10); pen dd = rgb(0,0,0.6) + linewidth(0.7) + linetype("4 4"), dr = rgb(0.8,0,0), dg = rgb(0,0.6,0), db = rgb(0,0,0.6)+linewidth(1); pair A=(0,1), B=(0,0), C=(2,0), D=(2,1), E=A/2, F=(2,.5), M=(1/3^.5,1), N=reflect(B,M)*A; D(B--M--D("N",N,NE)--B--D("C",C,SE)--D("D",D,NE)--M); D(D("M",M,plain.N)--D("A",A,NW)--D("B",B,SW),dd); D(D("E",E,W)--D("F",F,plain.E),dd); [/asy]

30^\circ

76.5625

2,228

The repeating decimals $0.abab\overline{ab}$ and $0.abcabc\overline{abc}$ satisfy \[0.abab\overline{ab}+0.abcabc\overline{abc}=\frac{33}{37},\] where $a,b$ , and $c$ are (not necessarily distinct) digits. Find the three-digit number $abc$ .

447

46.09375

2,229

Let $p$ be a prime number such that $p\equiv 1\pmod{4}$ . Determine $\sum_{k=1}^{\frac{p-1}{2}}\left \lbrace \frac{k^2}{p} \right \rbrace$ , where $\{x\}=x-[x]$ .

\frac{p-1}{4}

51.5625

2,230

In a finite sequence of real numbers the sum of any seven successive terms is negative and the sum of any eleven successive terms is positive. Determine the maximum number of terms in the sequence.

16

41.40625

2,231

**Q.** Find all polynomials $P: \mathbb{R \times R}\to\mathbb{R\times R}$ with real coefficients, such that $$ P(x,y) = P(x+y,x-y), \ \forall\ x,y \in \mathbb{R}. $$ *Proposed by TuZo*

P(x, y) = (a, b)

0

2,232

Let $X$ be a set with $n$ elements and $0 \le k \le n$ . Let $a_{n,k}$ be the maximum number of permutations of the set $X$ such that every two of them have at least $k$ common components (where a common component of $f$ and g is an $x \in X$ such that $f(x) = g(x)$ ). Let $b_{n,k}$ be the maximum number of permutations of the set $X$ such that every two of them have at most $k$ common components. (a) Show that $a_{n,k} \cdot b_{n,k-1} \le n!$ . (b) Let $p$ be prime, and find the exact value of $a_{p,2}$ .

(p-2)!

3.90625

2,233

Let $m$ and $n$ be positive integers such that $x=m+\sqrt{n}$ is a solution to the equation $x^2-10x+1=\sqrt{x}(x+1)$ . Find $m+n$ .

55

14.0625

2,234

In the plane there are $2020$ points, some of which are black and the rest are green. For every black point, the following applies: *There are exactly two green points that represent the distance $2020$ from that black point.* Find the smallest possible number of green dots. (Walther Janous)

45

0

2,235

Considering all numbers of the form $n = \lfloor \frac{k^3}{2012} \rfloor$ , where $\lfloor x \rfloor$ denotes the greatest integer less than or equal to $x$ , and $k$ ranges from $1$ to $2012$ , how many of these $n$ ’s are distinct?

1995

97.65625

2,236

A circle radius $320$ is tangent to the inside of a circle radius $1000$ . The smaller circle is tangent to a diameter of the larger circle at a point $P$ . How far is the point $P$ from the outside of the larger circle?

400

3.125

2,237

Find all positive integers $d$ for which there exist polynomials $P(x)$ and $Q(x)$ with real coefficients such that degree of $P$ equals $d$ and $$ P(x)^2+1=(x^2+1)Q(x)^2. $$

d

9.375

2,238

$ABCD$ is a cyclic quadrilateral inscribed in a circle of radius $5$ , with $AB=6$ , $BC=7$ , $CD=8$ . Find $AD$ .

\sqrt{51}

0

2,239

For every positive integer $k$ , let $\mathbf{T}_k = (k(k+1), 0)$ , and define $\mathcal{H}_k$ as the homothety centered at $\mathbf{T}_k$ with ratio $\tfrac{1}{2}$ if $k$ is odd and $\tfrac{2}{3}$ is $k$ is even. Suppose $P = (x,y)$ is a point such that $$ (\mathcal{H}_{4} \circ \mathcal{H}_{3} \circ \mathcal{H}_2 \circ \mathcal{H}_1)(P) = (20, 20). $$ What is $x+y$ ? (A *homothety* $\mathcal{H}$ with nonzero ratio $r$ centered at a point $P$ maps each point $X$ to the point $Y$ on ray $\overrightarrow{PX}$ such that $PY = rPX$ .)

256

17.1875

2,240

Find the total number of solutions to the following system of equations: \[ \begin{cases} a^2\plus{}bc\equiv a\pmod {37} b(a\plus{}d)\equiv b\pmod {37} c(a\plus{}d)\equiv c\pmod{37} bc\plus{}d^2\equiv d\pmod{37} ad\minus{}bc\equiv 1\pmod{37}\end{cases}\]

1

19.53125

2,241

Triangle $ABC$ is right angled at $A$ . The circle with center $A$ and radius $AB$ cuts $BC$ and $AC$ internally at $D$ and $E$ respectively. If $BD = 20$ and $DC = 16$ , determine $AC^2$ .

936

3.125

2,242

Let the three sides of a triangle be $\ell, m, n$ , respectively, satisfying $\ell>m>n$ and $\left\{\frac{3^\ell}{10^4}\right\}=\left\{\frac{3^m}{10^4}\right\}=\left\{\frac{3^n}{10^4}\right\}$ , where $\{x\}=x-\lfloor{x}\rfloor$ and $\lfloor{x}\rfloor$ denotes the integral part of the number $x$ . Find the minimum perimeter of such a triangle.

3003

2.34375

2,243

Let $m$ be a positive integer, and let $a_0, a_1,\ldots,a_m$ be a sequence of reals such that $a_0=37$ , $a_1=72$ , $a_m=0$ , and \[a_{k+1}=a_{k-1}-\frac{3}{a_k}\] for $k=1,2, \dots, m-1$ . Find $m$ .

889

97.65625

2,244

The isoelectric point of glycine is the pH at which it has zero charge. Its charge is $-\frac13$ at pH $3.55$ , while its charge is $\frac12$ at pH $9.6$ . Charge increases linearly with pH. What is the isoelectric point of glycine?

5.97

43.75

2,245

There are two round tables with $n{}$ dwarves sitting at each table. Each dwarf has only two friends: his neighbours to the left and to the right. A good wizard wants to seat the dwarves at one round table so that each two neighbours are friends. His magic allows him to make any $2n$ pairs of dwarves into pairs of friends (the dwarves in a pair may be from the same or from different tables). However, he knows that an evil sorcerer will break $n{}$ of those new friendships. For which $n{}$ is the good wizard able to achieve his goal no matter what the evil sorcerer does? *Mikhail Svyatlovskiy*

n

64.0625

2,246

Find all functions $f$ from the reals into the reals such that \[ f(ab) = f(a+b) \] for all irrational $a, b$ .

f(x) = c

67.96875

2,247

For a positive integer $n$ , there is a school with $2n$ people. For a set $X$ of students in this school, if any two students in $X$ know each other, we call $X$ *well-formed*. If the maximum number of students in a well-formed set is no more than $n$ , find the maximum number of well-formed set. Here, an empty set and a set with one student is regarded as well-formed as well.

3^n

0

2,248

The intersection of two squares with perimeter $8$ is a rectangle with diagonal length $1$ . Given that the distance between the centers of the two squares is $2$ , the perimeter of the rectangle can be expressed as $P$ . Find $10P$ .

25

7.03125

2,249

In a competition there are $18$ teams and in each round $18$ teams are divided into $9$ pairs where the $9$ matches are played coincidentally. There are $17$ rounds, so that each pair of teams play each other exactly once. After $n$ rounds, there always exists $4$ teams such that there was exactly one match played between these teams in those $n$ rounds. Find the maximum value of $n$ .

7

10.9375

2,250

In a room there are $144$ people. They are joined by $n$ other people who are each carrying $k$ coins. When these coins are shared among all $n + 144$ people, each person has $2$ of these coins. Find the minimum possible value of $2n + k$ .

50

93.75

2,251

Point D is from AC of triangle ABC so that 2AD=DC. Let DE be perpendicular to BC and AE intersects BD at F. It is known that triangle BEF is equilateral. Find <ADB?

90^\circ

21.875

2,252

Let $S_n$ be the sum of the reciprocals of the non-zero digits of the integers from 1 to $10^n$ inclusive. Find the smallest positive integer $n$ for which $S_n$ is an integer.

63

65.625

2,253

A terrain ( $ABCD$ ) has a rectangular trapezoidal shape. The angle in $A$ measures $90^o$ . $AB$ measures $30$ m, $AD$ measures $20$ m and $DC$ measures 45 m. This land must be divided into two areas of the same area, drawing a parallel to the $AD$ side . At what distance from $D$ do we have to draw the parallel? ![Image](https://1.bp.blogspot.com/-DnyNY3x4XKE/XNYvRUrLVTI/AAAAAAAAKLE/gohd7_S9OeIi-CVUVw-iM63uXE5u-WmGwCK4BGAYYCw/s400/image002.gif)

18.75 \text{ m}

0.78125

2,254

For the NEMO, Kevin needs to compute the product \[ 9 \times 99 \times 999 \times \cdots \times 999999999. \] Kevin takes exactly $ab$ seconds to multiply an $a$ -digit integer by a $b$ -digit integer. Compute the minimum number of seconds necessary for Kevin to evaluate the expression together by performing eight such multiplications. *Proposed by Evan Chen*

870

27.34375

2,255

We define the function $f(x,y)=x^3+(y-4)x^2+(y^2-4y+4)x+(y^3-4y^2+4y)$ . Then choose any distinct $a, b, c \in \mathbb{R}$ such that the following holds: $f(a,b)=f(b,c)=f(c,a)$ . Over all such choices of $a, b, c$ , what is the maximum value achieved by \[\min(a^4 - 4a^3 + 4a^2, b^4 - 4b^3 + 4b^2, c^4 - 4c^3 + 4c^2)?\]

1

14.84375

2,256

A sequence of vertices $v_1,v_2,\ldots,v_k$ in a graph, where $v_i=v_j$ only if $i=j$ and $k$ can be any positive integer, is called a $\textit{cycle}$ if $v_1$ is attached by an edge to $v_2$ , $v_2$ to $v_3$ , and so on to $v_k$ connected to $v_1$ . Rotations and reflections are distinct: $A,B,C$ is distinct from $A,C,B$ and $B,C,A$ . Supposed a simple graph $G$ has $2013$ vertices and $3013$ edges. What is the minimal number of cycles possible in $G$ ?

1001

94.53125

2,257

Gus has to make a list of $250$ positive integers, not necessarily distinct, such that each number is equal to the number of numbers in the list that are different from it. For example, if $15$ is a number from the list so the list contains $15$ numbers other than $15$ . Determine the maximum number of distinct numbers the Gus list can contain.

21

8.59375

2,258

At a certain grocery store, cookies may be bought in boxes of $10$ or $21.$ What is the minimum positive number of cookies that must be bought so that the cookies may be split evenly among $13$ people? *Author: Ray Li*

52

92.1875

2,259

An infinite sheet of paper is divided into equal squares, some of which are colored red. In each $2\times3$ rectangle, there are exactly two red squares. Now consider an arbitrary $9\times11$ rectangle. How many red squares does it contain? (The sides of all considered rectangles go along the grid lines.)

33

50.78125

2,260

Find all functions $f:\mathbb{N} \to \mathbb{N}$ such that for all $m,n\in \mathbb{N}$ : - $f(2)=2$ , - $f(mn)=f(m)f(n)$ , - $f(n+1)>f(n)$ .

f(n) = n

100

2,261

Define the *hotel elevator cubic*as the unique cubic polynomial $P$ for which $P(11) = 11$ , $P(12) = 12$ , $P(13) = 14$ , $P(14) = 15$ . What is $P(15)$ ? *Proposed by Evan Chen*

13

68.75

2,262

Four positive integers $a, b, c, d$ satisfy the condition: $a < b < c < d$ . For what smallest possible value of $d$ could the following condition be true: the arithmetic mean of numbers $a, b, c$ is twice smaller than the arithmetic mean of numbers $a, b, c, d$ ?

10

83.59375

2,263

Find all real numbers $x$ that satisfy the equation $$ \frac{x-2020}{1}+\frac{x-2019}{2}+\cdots+\frac{x-2000}{21}=\frac{x-1}{2020}+\frac{x-2}{2019}+\cdots+\frac{x-21}{2000}, $$ and simplify your answer(s) as much as possible. Justify your solution.

x = 2021

67.1875

2,264

A quadratic polynomial $p(x)$ with integer coefficients satisfies $p(41) = 42$ . For some integers $a, b > 41$ , $p(a) = 13$ and $p(b) = 73$ . Compute the value of $p(1)$ . *Proposed by Aaron Lin*

2842

4.6875

2,265

The polynomial $P$ is a quadratic with integer coefficients. For every positive integer $n$ , the integers $P(n)$ and $P(P(n))$ are relatively prime to $n$ . If $P(3) = 89$ , what is the value of $P(10)$ ?

859

0

2,266

Let $k$ be a real number such that the product of real roots of the equation $$ X^4 + 2X^3 + (2 + 2k)X^2 + (1 + 2k)X + 2k = 0 $$ is $-2013$ . Find the sum of the squares of these real roots.

4027

9.375

2,267

Find all natural numbers $n> 1$ for which the following applies: The sum of the number $n$ and its second largest divisor is $2013$ . (R. Henner, Vienna)

n = 1342

0

2,268

A student did not notice multiplication sign between two three-digit numbers and wrote it as a six-digit number. Result was 7 times more that it should be. Find these numbers. *(2 points)*

(143, 143)

0.78125

2,269

Suppose that each of $n$ people knows exactly one piece of information and all $n$ pieces are different. Every time person $A$ phones person $B$ , $A$ tells $B$ everything he knows, while tells $A$ nothing. What is the minimum of phone calls between pairs of people needed for everyone to know everything?

2n - 2

5.46875

2,270

Let $ S(n) $ be the sum of the squares of the positive integers less than and coprime to $ n $ . For example, $ S(5) = 1^2 + 2^2 + 3^2 + 4^2 $ , but $ S(4) = 1^2 + 3^2 $ . Let $ p = 2^7 - 1 = 127 $ and $ q = 2^5 - 1 = 31 $ be primes. The quantity $ S(pq) $ can be written in the form $$ \frac{p^2q^2}{6}\left(a - \frac{b}{c} \right) $$ where $ a $ , $ b $ , and $ c $ are positive integers, with $ b $ and $ c $ coprime and $ b < c $ . Find $ a $ .

7561

0.78125

2,271

When a function $f(x)$ is differentiated $n$ times ,the function we get id denoted $f^n(x)$ .If $f(x)=\dfrac {e^x}{x}$ .Find the value of \[\lim_{n \to \infty} \dfrac {f^ {2n}(1)}{(2n)!}\]

1

16.40625

2,272

Determine the smallest integer $k > 1$ such that there exist $k$ distinct primes whose squares sum to a power of $2$ .

k = 5

0

2,273

Region $ABCDEFGHIJ$ consists of $13$ equal squares and is inscribed in rectangle $PQRS$ with $A$ on $\overline{PQ}$ , $B$ on $\overline{QR}$ , $E$ on $\overline{RS}$ , and $H$ on $\overline{SP}$ , as shown in the figure on the right. Given that $PQ=28$ and $QR=26$ , determine, with proof, the area of region $ABCDEFGHIJ$ . [asy] size(200); defaultpen(linewidth(0.7)+fontsize(12)); pair P=(0,0), Q=(0,28), R=(26,28), S=(26,0), B=(3,28); draw(P--Q--R--S--cycle); picture p = new picture; draw(p, (0,0)--(3,0)^^(0,-1)--(3,-1)^^(0,-2)--(5,-2)^^(0,-3)--(5,-3)^^(2,-4)--(3,-4)^^(2,-5)--(3,-5)); draw(p, (0,0)--(0,-3)^^(1,0)--(1,-3)^^(2,0)--(2,-5)^^(3,0)--(3,-5)^^(4,-2)--(4,-3)^^(5,-2)--(5,-3)); transform t = shift(B) * rotate(-aSin(1/26^.5)) * scale(26^.5); add(t*p); label(" $P$ ",P,SW); label(" $Q$ ",Q,NW); label(" $R$ ",R,NE); label(" $S$ ",S,SE); label(" $A$ ",t*(0,-3),W); label(" $B$ ",B,N); label(" $C$ ",t*(3,0),plain.ENE); label(" $D$ ",t*(3,-2),NE); label(" $E$ ",t*(5,-2),plain.E); label(" $F$ ",t*(5,-3),plain.SW); label(" $G$ ",t*(3,-3),(0.81,-1.3)); label(" $H$ ",t*(3,-5),plain.S); label(" $I$ ",t*(2,-5),NW); label(" $J$ ",t*(2,-3),SW);[/asy]

338

0.78125

2,274

Let $S$ be the sum of the base 10 logarithms of all the proper divisors of 1000000. What is the integer nearest to $S$ ?

141

62.5

2,275

Two players play a game on a pile of $n$ beans. On each player's turn, they may take exactly $1$ , $4$ , or $7$ beans from the pile. One player goes first, and then the players alternate until somebody wins. A player wins when they take the last bean from the pile. For how many $n$ between $2014$ and $2050$ (inclusive) does the second player win?

14

91.40625

2,276

**Q11.** Let be given a sequense $a_1=5, \; a_2=8$ and $a_{n+1}=a_n+3a_{n-1}, \qquad n=1,2,3,...$ Calculate the greatest common divisor of $a_{2011}$ and $a_{2012}$ .

1

5.46875

2,277

It is given that there exists a unique triple of positive primes $(p,q,r)$ such that $p<q<r$ and \[\dfrac{p^3+q^3+r^3}{p+q+r} = 249.\] Find $r$ .

r = 19

0

2,278

Let $p$ prime and $m$ a positive integer. Determine all pairs $( p,m)$ satisfying the equation: $ p(p+m)+p=(m+1)^3$

(2, 1)

18.75

2,279

$p(x)$ is the cubic $x^3 - 3x^2 + 5x$ . If $h$ is a real root of $p(x) = 1$ and $k$ is a real root of $p(x) = 5$ , find $h + k$ .

h + k = 2

0

2,280

A crazy physicist has discovered a new particle called an omon. He has a machine, which takes two omons of mass $a$ and $b$ and entangles them; this process destroys the omon with mass $a$ , preserves the one with mass $b$ , and creates a new omon whose mass is $\frac 12 (a+b)$ . The physicist can then repeat the process with the two resulting omons, choosing which omon to destroy at every step. The physicist initially has two omons whose masses are distinct positive integers less than $1000$ . What is the maximum possible number of times he can use his machine without producing an omon whose mass is not an integer? *Proposed by Michael Kural*

9

85.15625

2,281

A mustache is created by taking the set of points $(x, y)$ in the $xy$ -coordinate plane that satisfy $4 + 4 \cos(\pi x/24) \le y \le 6 + 6\cos(\pi x/24)$ and $-24 \le x \le 24$ . What is the area of the mustache?

96

96.09375

2,282

Let $\{a_n\}_{n=1}^{\infty}$ and $\{b_n\}_{n=1}^{\infty}$ be sequences of integers such that $a_1 = 20$ , $b_1 = 15$ , and for $n \ge 1$ , \[\left\{\begin{aligned} a_{n+1}&=a_n^2-b_n^2, b_{n+1}&=2a_nb_n-b_n^2 \end{aligned}\right.\] Let $G = a_{10}^2-a_{10}b_{10}+b_{10}^2$ . Determine the number of positive integer factors of $G$ . *Proposed by Michael Ren*

525825

0

2,283

Let $ n\geq 3 $ be an integer and let $ x_1,x_2,\ldots,x_{n-1} $ be nonnegative integers such that \begin{eqnarray*} \ x_1 + x_2 + \cdots + x_{n-1} &=& n x_1 + 2x_2 + \cdots + (n-1)x_{n-1} &=& 2n-2. \end{eqnarray*} Find the minimal value of $ F(x_1,x_2,\ldots,x_n) = \sum_{k=1}^{n-1} k(2n-k)x_k $ .

3n(n-1)

3.90625

2,284

Let $a_1, a_2, a_3, a_4$ be integers with distinct absolute values. In the coordinate plane, let $A_1=(a_1,a_1^2)$ , $A_2=(a_2,a_2^2)$ , $A_3=(a_3,a_3^2)$ and $A_4=(a_4,a_4^2)$ . Assume that lines $A_1A_2$ and $A_3A_4$ intersect on the $y$ -axis at an acute angle of $\theta$ . The maximum possible value for $\tan \theta$ can be expressed in the form $\dfrac mn$ for relatively prime positive integers $m$ and $n$ . Find $100m+n$ . *Proposed by James Lin*

503

0

2,285

Consider the sequence $$ 1,7,8,49,50,56,57,343\ldots $$ which consists of sums of distinct powers of $7$ , that is, $7^0$ , $7^1$ , $7^0+7^1$ , $7^2$ , $\ldots$ in increasing order. At what position will $16856$ occur in this sequence?

36

10.15625

2,286

Compute the maximum integer value of $k$ such that $2^k$ divides $3^{2n+3}+40n-27$ for any positive integer $n$ .

6

20.3125

2,287

Find the greatest positive real number $M$ such that for all positive real sequence $(a_n)$ and for all real number $m < M$ , it is possible to find some index $n \ge 1$ that satisfies the inequality $a_1 + a_2 + a_3 + ...+ a_n +a_{n+1} > m a_n$ .

M = 4

0

2,288

Find the number of pairs of positive integers $a$ and $b$ such that $a\leq 100\,000$ , $b\leq 100\,000$ , and $$ \frac{a^3-b}{a^3+b}=\frac{b^2-a^2}{b^2+a^2}. $$

10

46.875

2,289

Suppose that $m$ and $n$ are relatively prime positive integers with $A = \tfrac mn$ , where \[ A = \frac{2+4+6+\dots+2014}{1+3+5+\dots+2013} - \frac{1+3+5+\dots+2013}{2+4+6+\dots+2014}. \] Find $m$ . In other words, find the numerator of $A$ when $A$ is written as a fraction in simplest form. *Proposed by Evan Chen*

2015

85.15625

2,290

Each person stands on a whole number on the number line from $0$ to $2022$ . In each turn, two people are selected by a distance of at least $2$ . These go towards each other by $1$ . When no more such moves are possible, the process ends. Show that this process always ends after a finite number of moves, and determine all possible configurations where people can end up standing. (whereby is for each configuration is only of interest how many people stand at each number.) *(Birgit Vera Schmidt)* <details><summary>original wording</summary>Bei jeder ganzen Zahl auf dem Zahlenstrahl von 0 bis 2022 steht zu Beginn eine Person. In jedem Zug werden zwei Personen mit Abstand mindestens 2 ausgewählt. Diese gehen jeweils um 1 aufeinander zu. Wenn kein solcher Zug mehr möglich ist, endet der Vorgang. Man zeige, dass dieser Vorgang immer nach endlich vielen Zügen endet, und bestimme alle möglichen Konfigurationen, wo die Personen am Ende stehen können. (Dabei ist für jede Konfiguration nur von Interesse, wie viele Personen bei jeder Zahl stehen.)</details>

1011

1.5625

2,291

A sequence $a_1, a_2, \ldots$ satisfies $a_1 = \dfrac 52$ and $a_{n + 1} = {a_n}^2 - 2$ for all $n \ge 1.$ Let $M$ be the integer which is closest to $a_{2023}.$ The last digit of $M$ equals $$ \mathrm a. ~ 0\qquad \mathrm b.~2\qquad \mathrm c. ~4 \qquad \mathrm d. ~6 \qquad \mathrm e. ~8 $$

4

3.90625

2,292

Which number is greater: $$ A=\frac{2.00\ldots04}{1.00\ldots04^2+2.00\ldots04},\text{ or }B=\frac{2.00\ldots02}{1.00\ldots02^2+2.00\ldots02}, $$ where each of the numbers above contains $1998$ zeros?

B

69.53125

2,293

The target below is made up of concentric circles with diameters $4$ , $8$ , $12$ , $16$ , and $20$ . The area of the dark region is $n\pi$ . Find $n$ . [asy] size(150); defaultpen(linewidth(0.8)); int i; for(i=5;i>=1;i=i-1) { if (floor(i/2)==i/2) { filldraw(circle(origin,4*i),white); } else { filldraw(circle(origin,4*i),red); } } [/asy]

60

34.375

2,294

In circle $\Omega$ , let $\overline{AB}=65$ be the diameter and let points $C$ and $D$ lie on the same side of arc $\overarc{AB}$ such that $CD=16$ , with $C$ closer to $B$ and $D$ closer to $A$ . Moreover, let $AD, BC, AC,$ and $BD$ all have integer lengths. Two other circles, circles $\omega_1$ and $\omega_2$ , have $\overline{AC}$ and $\overline{BD}$ as their diameters, respectively. Let circle $\omega_1$ intersect $AB$ at a point $E \neq A$ and let circle $\omega_2$ intersect $AB$ at a point $F \neq B$ . Then $EF=\frac{m}{n}$ , for relatively prime integers $m$ and $n$ . Find $m+n$ . [asy] size(7cm); pair A=(0,0), B=(65,0), C=(117/5,156/5), D=(125/13,300/13), E=(23.4,0), F=(9.615,0); draw(A--B--C--D--cycle); draw(A--C); draw(B--D); dot(" $A$ ", A, SW); dot(" $B$ ", B, SE); dot(" $C$ ", C, NE); dot(" $D$ ", D, NW); dot(" $E$ ", E, S); dot(" $F$ ", F, S); draw(circle((A + C)/2, abs(A - C)/2)); draw(circle((B + D)/2, abs(B - D)/2)); draw(circle((A + B)/2, abs(A - B)/2)); label(" $\mathcal P$ ", (A + B)/2 + abs(A - B)/2 * dir(-45), dir(-45)); label(" $\mathcal Q$ ", (A + C)/2 + abs(A - C)/2 * dir(-210), dir(-210)); label(" $\mathcal R$ ", (B + D)/2 + abs(B - D)/2 * dir(70), dir(70)); [/asy] *Proposed by **AOPS12142015***

961

0

2,295

Let $ABCD$ be a square, and let $M$ be the midpoint of side $BC$ . Points $P$ and $Q$ lie on segment $AM$ such that $\angle BPD=\angle BQD=135^\circ$ . Given that $AP<AQ$ , compute $\tfrac{AQ}{AP}$ .

\sqrt{5}

0.78125

2,296

Starting from 37, adding 5 before each previous term, forms the following sequence: \[37,537,5537,55537,555537,...\] How many prime numbers are there in this sequence?

1

91.40625

2,297

Let $f(t)$ be the cubic polynomial for $t$ such that $\cos 3x=f(\cos x)$ holds for all real number $x$ . Evaluate \[\int_0^1 \{f(t)\}^2 \sqrt{1-t^2}dt\]

\frac{\pi}{8}

39.84375

2,298

Ana has $22$ coins. She can take from her friends either $6$ coins or $18$ coins, or she can give $12$ coins to her friends. She can do these operations many times she wants. Find the least number of coins Ana can have.

4

83.59375

2,299

Find the least $k$ for which the number $2010$ can be expressed as the sum of the squares of $k$ integers.

k=3

36.71875