id stringlengths 4 4 | problem_markdown stringlengths 36 3.59k | solutions_markdown listlengths 0 10 | images images listlengths 0 15 | country stringclasses 58
values | competition stringlengths 3 108 ⌀ | topics_flat listlengths 0 12 | language stringclasses 18
values | problem_type stringclasses 4
values | final_answer stringlengths 1 1.22k ⌀ |
|---|---|---|---|---|---|---|---|---|---|
0g1d | Problem:
Sei $k$ ein Kreis und $AB$ eine Sehne von $k$, sodass der Mittelpunkt von $k$ nicht auf $AB$ liegt. Sei $C$ ein von $A$ und $B$ verschiedener Punkt auf $k$. Für jede Wahl von $C$ seien $P_{C}$ und $Q_{C}$ die Projektionen von $A$ auf $BC$ respektive $B$ auf $AC$. Weiter sei $O_{C}$ der Umkreismittelpunkt des ... | [
"Solution:\n\nWir bemerken zuerst, dass $ABPQ$ wegen $\\angle AQB=\\angle APB=90^\\circ$ ein Sehnenviereck ist. Sei $M$ der Mittelpunkt der Sehne $AB$. Aus der Umkehrung von Thales im Dreieck $ABP$ folgt, dass $M$ der Umkreismittelpunkt von $ABPQ$ ist.\n\nWegen des Peripheriewinkelsatzes ist $\\angle ACB$ unabhängi... | Switzerland | IMO-Selektion | [
"Geometry > Plane Geometry > Quadrilaterals > Cyclic quadrilaterals",
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing",
"Geometry > Plane Geometry > Miscellaneou... | null | proof only | null | |
0apa | Problem:
Find all real values of $x$ satisfying the inequality
$$
\sqrt{\left(\frac{1}{2-x}+1\right)^{2}} \geq 2
$$ | [
"Solution:\nWe recall that $\\sqrt{a^{2}}=|a|$ for any $a \\in \\mathbb{R}$. Thus, the given inequality is equivalent to\n$$\n\\left|\\frac{3-x}{2-x}\\right| \\geq 2\n$$\nwhich is further equivalent to the following compound inequality:\n$$\n\\frac{3-x}{2-x} \\geq 2 \\quad \\text{or} \\quad \\frac{3-x}{2-x} \\leq -... | Philippines | Tenth Philippine Mathematical Olympiad | [
"Algebra > Equations and Inequalities > Linear and quadratic inequalities"
] | null | proof and answer | [1,2) ∪ (2, 7/3] | |
0cxl | Prove that among any nine divisors of $30^{2010}$ there are two whose product is a perfect square. | [
"Let us factor $30^{2010} = 2^{2010} \\cdot 3^{2010} \\cdot 5^{2010}$.\n\nAny divisor $d$ of $30^{2010}$ can be written as $d = 2^a 3^b 5^c$ where $0 \\leq a, b, c \\leq 2010$.\n\nThe product of two divisors $d_1 = 2^{a_1} 3^{b_1} 5^{c_1}$ and $d_2 = 2^{a_2} 3^{b_2} 5^{c_2}$ is a perfect square if and only if $a_1 ... | Saudi Arabia | SAMC | [
"Number Theory > Divisibility / Factorization",
"Discrete Mathematics > Combinatorics > Pigeonhole principle"
] | English | proof only | null | |
08q9 | Problem:
Let $ABC$ be a right-angled triangle with $\hat{A}=90^{\circ}$. Let $K$ be the midpoint of $BC$, and let $AKLM$ be a parallelogram with centre $C$. Let $T$ be the intersection of the line $AC$ and the perpendicular bisector of $BM$. Let $\omega_{1}$ be the circle with centre $C$ and radius $CA$ and let $\omega... | [
"Solution:\nLet $M'$ be the symmetric point of $M$ with respect to $T$. Observe that $T$ is equidistant from $B$ and $M$, therefore $M$ belongs on $\\omega_{2}$ and $M'M$ is a diameter of $\\omega_{2}$. It suffices to prove that $M'A$ is perpendicular to $LM$, or equivalently, to $AK$. To see this, let $S$ be the p... | JBMO | Junior Balkan Mathematical Olympiad Shortlist | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Transformations > Rotation",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing",
"Geometry > Plane Geometry > Miscellaneous > Construc... | null | proof only | null | |
0hj4 | Problem:
Do there exist 100 consecutive positive integers such that their sum is a prime number? | [
"Solution:\n\nNo. Let $n, n+1, \\ldots, n+99$ be any 100 consecutive positive integers. Then\n$$\nn + (n+1) + (n+2) + \\cdots + (n+99) = 100n + (1+2+\\cdots+99).\n$$\nHowever,\n$$\n1+2+\\cdots+99 = (1+99) + (2+98) + (3+97) + \\cdots + (49+51) + 50 = 49 \\cdot 100 + 50 = 50(2 \\cdot 49 + 1) = 50 \\cdot 99.\n$$\nThus... | United States | Berkeley Math Circle Monthly Contest 5 | [
"Number Theory > Divisibility / Factorization > Prime numbers",
"Number Theory > Divisibility / Factorization > Factorization techniques",
"Algebra > Algebraic Expressions > Sequences and Series > Sums and products"
] | null | proof and answer | No | |
07hz | In the triangle $ABC$, variable points $D$, $E$, $F$ are on the sides $BC$, $CA$, $AB$ respectively such that the triangle $DFE$ is similar to the triangle $ABC$ in the same order as written. Circumcircles of $BDF$ and $CDE$ intersect the circumcircle of $ABC$ at $P$ and $Q$, respectively for the second time. Prove tha... | [
"Let the tangent of $\\odot(ABC)$ at $A$ intersect $BC$ at $G$ and $FE \\cap AG = H$, $FD \\cap AC = I$, $ED \\cap AB = J$. We'll show that $\\odot(DPQ)$ passes through the fixed point $G$.\n\nWe claim that $A$, $H$, $J$, $Q$, $E$ are concyclic. Analogously, $A$, $F$, $P$, $H$, $I$ are also concyclic. It follows fr... | Iran | 40th Iranian Mathematical Olympiad | [
"Geometry > Plane Geometry > Circles > Tangents",
"Geometry > Plane Geometry > Quadrilaterals > Cyclic quadrilaterals",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing"
] | null | proof only | null | |
0go4 | $D$, $E$, $F$ are points on the sides $AB$, $BC$, $CA$, respectively, of a triangle $ABC$ such that $AD = AF$, $BD = BE$ and $DE = DF$. Let $I$ be the incircle of the triangle $ABC$, and let $K$ be the point of intersection of the line $BI$ and the tangent line through $A$ to the circumcircle of the triangle $ABI$. Sho... | [
"From $AD = AF$, $BD = BE$ and $DE = DF$ we obtain $AD \\sin(\\angle A/2) = BD \\sin(\\angle B/2)$. Using this and applying the law of sines to the triangle $AIB$, we get $AI/BI = AD/BD = AK/BE$. Since $AK$ is tangent to the circumcircle of $AIB$, we also have $\\angle KAI = \\angle ABI = \\angle EBI$. Hence the tr... | Turkey | Team Selection Test for IMO 2010 | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Triangles > Triangle trigonometry",
"Geometry > Plane Geometry > Circles > Tangents",
"Geometry > Plane Geometry > Quadrilaterals > Cyclic quad... | English | proof only | null | |
02t9 | Problem:
O herói de um desenho animado enfrenta mais uma vez seu arqui-inimigo e precisa desferir seu famoso golpe do Raio Reflexivo. No quadrado da figura abaixo, o raio deverá, partindo de $F$ ricochetear, exatamente uma vez nos lados $C D, A D$ e $A B$, nesta ordem, antes de atingir o inimigo na posição $E$. Sempre ... | [
"Solution:\nSe a parede onde o raio reflete fosse um espelho, a sua trajetória também \"apareceria\" no outro lado do espelho como uma continuação em linha reta da trajetória inicial. Assim, após refletirmos o quadrado três vezes ao longo dos lados onde o raio incide, conseguiremos traçar uma trajetória imaginária ... | Brazil | Brazilian Mathematical Olympiad | [
"Geometry > Plane Geometry > Miscellaneous > Distance chasing",
"Geometry > Plane Geometry > Miscellaneous > Constructions and loci"
] | null | proof and answer | 2 sqrt(61) seconds | |
04gp | In the triangle $ABC$ we have $\angle ABC = 2\angle BAC$. Prove that $|AC| < 2|BC|$. (Ilko Brnetić) | [
"Let $\\angle BAC = \\alpha$, so $\\angle ABC = 2\\alpha$.\n\nIn triangle $ABC$, the sum of angles is $180^\\circ$:\n$$\n\\alpha + 2\\alpha + \\angle BCA = 180^\\circ\n$$\nSo $\\angle BCA = 180^\\circ - 3\\alpha$.\n\nLet $|AB| = c$, $|BC| = a$, $|CA| = b$.\n\nBy the Law of Sines:\n$$\n\\frac{a}{\\sin \\alpha} = \\f... | Croatia | Mathematica competitions in Croatia | [
"Geometry > Plane Geometry > Triangles > Triangle trigonometry",
"Geometry > Plane Geometry > Triangles > Triangle inequalities",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing"
] | English | proof only | null | |
0d0z | Let $a$, $b$, $c$ be positive integers. Prove that if the numbers $\frac{a^2}{a+b}$, $\frac{b^2}{b+c}$, $\frac{c^2}{c+a}$ are integers and primes, then $a = b = c$. | [
"We will use the following result:\n\n**Lemma.** If $x$ and $y$ are positive integers such that $\\frac{x^2}{x+y}$ is an integer and prime, then $y \\ge x$.\n\n**Proof of Lemma.** Assume that $\\frac{x^2}{x+y} = p$, where $p$ is a prime.\nWe have $py = x(x - p)$, so $p \\mid x(x - p)$, i.e. $p \\mid x$. Let $x = up... | Saudi Arabia | Saudi Arabia Mathematical Competitions 2012 | [
"Number Theory > Divisibility / Factorization > Prime numbers"
] | English | proof only | null | |
07wc | Let $f^{(n)}$ denote the $n$-fold iterate of a function, i.e.
$$
f^{(1)}(x) = f(x), \quad f^{(2)}(x) = f(f(x)), \quad f^{(3)}(x) = f(f(f(x))), \dots
$$
and let $f : [0, \infty) \to [0, \infty)$ be such that
$$
f^{(2)}(x) = s f(x) + t x, \quad x \ge 0.
$$
Assuming only that $s, t \in \mathbb{R}$ are non-zero, show that ... | [
"Define a sequence $(p_i)_{i \\ge 0}$ by letting $p_0 = p$ and $p_i = f^{(i)}(p)$ for $i \\ge 1$. Putting $x = p_n$ in the given equation, $f^{(2)}(x) = s f(x) + t x$, gives the following linear recurrence\n$$\np_{n+2} = s p_{n+1} + t p_n. \\qquad (25)\n$$\nApplying $f^{(i)}$ for $i \\ge 1$ to the condition $f^{(n+... | Ireland | IRL_ABooklet_2023 | [
"Algebra > Algebraic Expressions > Functional Equations > Injectivity / surjectivity",
"Algebra > Algebraic Expressions > Sequences and Series > Recurrence relations",
"Algebra > Algebraic Expressions > Polynomials > Roots of unity",
"Algebra > Intermediate Algebra > Complex numbers",
"Algebra > Algebraic E... | English | proof only | null | |
01wu | a polygon (not necessarily convex) on the coordinate plane is called plump if it satisfies the following three conditions:
* coordinates of all vertices are integers;
* each side forms an angle of $0^\circ, 90^\circ$ or $45^\circ$ with the abscissa axis;
* internal angles belong to the interval $[90^\circ, 270^\circ]$... | [] | Belarus | 69th Belarusian Mathematical Olympiad | [
"Geometry > Plane Geometry > Miscellaneous > Constructions and loci",
"Discrete Mathematics > Combinatorics > Invariants / monovariants",
"Discrete Mathematics > Combinatorics > Coloring schemes, extremal arguments"
] | English | proof only | null | |
09bo | $ABC$ тэгш өнцөгт гурвалжны $\angle ACB = 90^\circ$ ба $CB > CA$ болно. $CB$ катетаар диаметрээ хийсэн хагас тойрог дээр $AC = CQ$ байхаар $Q$ цэгийг, $CB$ катет дээр $BQ = BP$ байхаар $P$ цэгийг тус тус авав. $AP$-ийн тойрогтой огтлолцох цэг $S$ бол $\angle CBS = \angle QBS$ гэе батал. (Хагас тойрог ба $A$ цэг $BC$-ий... | [
"\n\nӨгөгдсөн нөхцөлөөс $\\triangle ACQ$, $\\triangle PBQ$-үүд нь адил хажуут гурвалжин болно. $BC$ тал диаметртэй хагас тойргийн хувьд $AC$ катет нь шүргэгч болно. Иймд $\\angle ACQ = \\frac{1}{2} \\cdot QC = \\angle CBQ$ байна.\n$$\n\\triangle ACQ \\sim \\triangle PBQ \\text{ боллоо.}\n$$... | Mongolia | Mongolian Mathematical Olympiad 46 | [
"Geometry > Plane Geometry > Circles > Tangents",
"Geometry > Plane Geometry > Quadrilaterals > Cyclic quadrilaterals",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing"
] | Mongolian | proof only | null | |
0j7b | Problem:
An independent set of a graph $G$ is a set of vertices of $G$ such that no two vertices among these are connected by an edge. If $G$ has $2000$ vertices, and each vertex has degree $10$, find the maximum possible number of independent sets that $G$ can have. | [
"Solution:\n\nAnswer: $2047^{100}$\n\nThe upper bound is obtained when $G$ is a disjoint union of bipartite graphs, each of which has $20$ vertices with $10$ in each group such that every pair of vertices not in the same group are connected."
] | United States | Harvard-MIT Mathematics Tournament | [
"Discrete Mathematics > Graph Theory",
"Discrete Mathematics > Combinatorics > Coloring schemes, extremal arguments"
] | null | proof and answer | 2047^{100} | |
0982 | Problem:
Fie piramida $V A B C$, în care $A B=7~\mathrm{cm}$, $A C=5~\mathrm{cm}$, $B C=8~\mathrm{cm}$, $V B=6~\mathrm{cm}$, iar unghiurile diedre de la baza $A B C$ sunt congruente. Să se determine distanța de la punctul $P$ la muchia $V A$, unde $A P$ este bisectoare în triunghiul $A B C$. | [
"Solution:\n\nProiecția vârfului $V$ pe baza $A B C$ este centrul $O$ al cercului înscris în triunghiul $A B C$. Fie $M$ și $N$ punctele de tangență ale laturilor $A B$ și $B C$, respectiv, cu cercul înscris în triunghiul $A B C$. Utilizând formula lui Heron, calculăm $\\mathcal{A}_{\\triangle A B C}=10 \\sqrt{3}~\... | Moldova | Olimpiada Republicană la Matematică | [
"Geometry > Solid Geometry > Other 3D problems",
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Circles > Tangents",
"Geometry > Plane Geometry > Miscellaneous > Distance chasing"
] | null | proof and answer | 2√210/9 cm | |
04ca | $ABCDA_1B_1C_1D_1$ is a cube of edge length $a$. A plane is set through the vertices $A$ and $C_1$ and the midpoint of edge $\overline{BB_1}$. Determine the area of the intersection of the cube and the plane. | [] | Croatia | Mathematica competitions in Croatia | [
"Geometry > Solid Geometry > Other 3D problems",
"Algebra > Linear Algebra > Vectors"
] | English | proof and answer | a^2*sqrt(6)/2 | |
02cm | Problem:
Uma estratégia com um número muito grande - Carlos escreveu em seguida todos os números de 1 a 60 :
$$
1234567891011121314 \cdots 57585960
$$
Depois ele riscou 100 algarismos de modo que o número formado com os algarismos que não foram riscados fôsse o maior possível, sem mudar a ordem inicial de como os al... | [
"Solution:\n\n9999785960 ."
] | Brazil | Desafios | [
"Discrete Mathematics > Combinatorics > Games / greedy algorithms",
"Discrete Mathematics > Algorithms"
] | null | final answer only | 9999785960 | |
0dh0 | Let $ABC$ be a right-angled triangle with $\angle A = 90^\circ$ and let $AD$ be an altitude of the triangle $ABC$. Let $J$, $K$ be the incenters of the triangles $ABD$, $ACD$ respectively. Let $JK$ intersect $AB$, $AC$ at $E$, $F$ respectively. Prove that $AE = AF$. | [] | Saudi Arabia | Saudi Arabian IMO Booklet | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Analytic / Coordinate Methods > Cartesian coordinates"
] | English | proof only | null | |
0hkn | Problem:
Each of Alice, Bob, and Carol is either a consistent truth-teller or a consistent liar. Alice states: "At least one of Bob or Carol is a truth-teller." Bob states: "Alice and Carol are both truth-tellers." Carol states: "If Alice is a truth-teller, so too is Bob." Must they all be truth-tellers? | [
"Solution:\n\nYes. If Carol were a liar, Alice would have to be a truth-teller while Bob would have to be a liar. However, Bob would then be telling the truth, a contradiction.\n\nThus Carol is telling the truth. Alice's statement is then true as well, and thus Bob's statement is also true. Hence, all logicians mus... | United States | Berkeley Math Circle: Monthly Contest 2 | [
"Discrete Mathematics > Logic"
] | null | proof and answer | Yes, they must all be truth-tellers. | |
08q6 | Problem:
Let $ABC$ be a triangle with incenter $I$. The points $D$ and $E$ lie on the segments $CA$ and $BC$ respectively, such that $CD = CE$. Let $F$ be a point on the segment $CD$. Prove that the quadrilateral $ABEF$ is circumscribable if and only if the quadrilateral $DIEF$ is cyclic. | [
"Solution:\nSince $CD = CE$ it means that $E$ is the reflection of $D$ on the bisector of $\\angle ACB$, i.e. the line $CI$. Let $G$ be the reflection of $F$ on $CI$. Then $G$ lies on the segment $CE$, the segment $EG$ is the reflection of the segment $DF$ on the line $CI$. Also, the quadrilateral $DEGF$ is cyclic ... | JBMO | Junior Balkan Mathematical Olympiad Shortlist | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Quadrilaterals > Cyclic quadrilaterals",
"Geometry > Plane Geometry > Quadrilaterals > Inscribed/circumscribed quadrilaterals",
"Geometry > Pla... | null | proof only | null | |
0js1 | Problem:
Quadrilateral $ABCD$ satisfies $AB = 8$, $BC = 5$, $CD = 17$, $DA = 10$. Let $E$ be the intersection of $AC$ and $BD$. Suppose $BE : ED = 1 : 2$. Find the area of $ABCD$. | [
"Solution:\n\nSince $BE : ED = 1 : 2$, we have $[ABC] : [ACD] = 1 : 2$.\n\nSuppose we cut off triangle $ACD$, reflect it across the perpendicular bisector of $AC$, and re-attach it as triangle $A' C' D'$ (so $A' = C$, $C' = A$).\n\nTriangles $ABC$ and $C'A'D'$ have vertex $A = C'$ and bases $BC$ and $A'D'$. Their a... | United States | HMMT November 2016 | [
"Geometry > Plane Geometry > Quadrilaterals",
"Geometry > Plane Geometry > Miscellaneous > Constructions and loci",
"Geometry > Plane Geometry > Miscellaneous > Distance chasing"
] | null | proof and answer | 60 | |
0fvg | Problem:
Im Dreieck $A B C$ sei $D$ der Schnittpunkt von $B C$ mit der Winkelhalbierenden von $\angle B A C$. Der Umkreismittelpunkt von $\triangle A B C$ falle mit dem Inkreismittelpunkt von $\triangle A D C$ zusammen. Finde die Winkel von $\triangle A B C$. | [
"Solution:\n\nWie üblich seien $\\alpha=\\angle B A C$, $\\beta=\\angle C B A$ und $\\gamma=\\angle A C B$. Der gemeinsame Mittelpunkt der beiden erwähnten Kreise sei $O$. Als Hilfslinien werden die Strecken von $O$ zu $A$, $B$ und $C$ eingezeichnet.\nEs folgt nun der Reihe nach (Begründungen jeweils in Klammer):\n... | Switzerland | Vorrundenprüfung | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing"
] | null | proof and answer | ∠A = 72°, ∠B = 72°, ∠C = 36° | |
0b6w | In the triangle $ABC$, the excircle $C(I_a)$ relative to $BC$ is tangent to the straight lines $BC$, $CA$, $AB$ at $D$, $E$, respectively $F$. The angle bisector of $\angle BI_aC$ meets $BC$ at $M$ and $AM$ meets $EF$ at $P$. Prove that $DP$ is the angle bisector of $\angle FDE$. | [] | Romania | Shortlisted Problems for the Romanian NMO | [
"Geometry > Plane Geometry > Circles > Tangents",
"Geometry > Plane Geometry > Advanced Configurations > Polar triangles, harmonic conjugates",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing"
] | English | proof only | null | |
0a7n | Problem:
Let $O$ be an interior point in the equilateral triangle $ABC$, of side length $a$. The lines $AO$, $BO$, and $CO$ intersect the sides of the triangle in the points $A_1$, $B_1$, and $C_1$. Show that
$$
|OA_1| + |OB_1| + |OC_1| < a
$$ | [
"Solution:\n\nLet $H_A$, $H_B$, and $H_C$ be the orthogonal projections of $O$ on $BC$, $CA$, and $AB$, respectively. Because $60^{\\circ} < \\angle OA_1B < 120^{\\circ}$,\n$$\n|OH_A| = |OA_1| \\sin(\\angle OA_1B) > |OA_1| \\frac{\\sqrt{3}}{2}\n$$\nIn the same way,\n$$\n|OH_B| > |OB_1| \\frac{\\sqrt{3}}{2} \\quad \... | Nordic Mathematical Olympiad | Nordic Mathematical Contest, NMC 8 | [
"Geometry > Plane Geometry > Geometric Inequalities > Triangle inequalities",
"Geometry > Plane Geometry > Triangles > Triangle trigonometry",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing"
] | null | proof only | null | |
0cdb | Determine all functions $f : \mathbb{R} \to \mathbb{R}$ such that:
$$
f(xf(x) + f(y)) = f(f(x^2)) + y, \quad \forall x, y \in \mathbb{R}.
$$ | [
"We claim that the solutions are $f_1 = 1_{\\mathbb{R}}$ and $f_2 = -1_{\\mathbb{R}}$.\n\nFor $x = 0$ we obtain $f(f(y)) = f(f(0)) + y$, for each $y \\in \\mathbb{R}$, so $f$ is an one-to-one function.\n\nFor $y = 0$ we have $f(xf(x) + f(0)) = f(f(x^2))$, $\\forall x \\in \\mathbb{R}$, which, due to $f$ being one-t... | Romania | THE 73rd ROMANIAN MATHEMATICAL OLYMPIAD - DISTRICT ROUND | [
"Algebra > Algebraic Expressions > Functional Equations > Injectivity / surjectivity"
] | null | proof and answer | f(x) = x for all real x, or f(x) = -x for all real x | |
0apl | Problem:
The area of a trapezoid is three times that of an equilateral triangle. If the heights of the trapezoid and the triangle are both equal to $8 \sqrt{3}$, what is the length of the median of the trapezoid? | [
"Solution:\n\nThe height of an equilateral triangle is $\\frac{\\sqrt{3}}{2}$ times the length of each of its sides. Thus, the length of one side of the equilateral triangle is $\\frac{2}{\\sqrt{3}} (8 \\sqrt{3}) = 16$, and its area is\n$$\n\\frac{1}{2} (8 \\sqrt{3})(16) = 64 \\sqrt{3}\n$$\nSince the area of the tr... | Philippines | Tenth Philippine Mathematical Olympiad | [
"Geometry > Plane Geometry > Triangles > Triangle trigonometry",
"Geometry > Plane Geometry > Quadrilaterals"
] | null | final answer only | 24 | |
04s7 | On a circle of radius $r$, the distinct points $A, B, C, D$, and $E$ lie in this order, satisfying $AB = CD = DE > r$. Show that the triangle with vertices lying in the centroids of the triangles $ABD$, $BCD$, and $ADE$ is obtuse. | [
"Denote by $P$, $Q$, and $R$ the centroids of the triangles $ABD$, $BCD$, and $ADE$, respectively. Let $K$ and $L$ be the midpoints of the segments $BD$ and $AD$, respectively. Since $P$ and $Q$ are centroids, they divide in the same ratio the medians $AK$ and $CK$, respectively. That is, $AP : PK = CQ : QK = 2 : 1... | Czech Republic | 15th Czech-Polish-Slovak Mathematics Competition | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Transformations > Homothety",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing",
"Geometry > Plane Geometry > Analytic / Coordinate M... | English | proof only | null | |
03x6 | Let $f(x, y, z) = \frac{x(2y-z)}{1+x+3y} + \frac{y(2z-x)}{1+y+3z} + \frac{z(2x-y)}{1+z+3x}$, where $x, y, z \ge 0$, and $x+y+z = 1$. Find the maximum value and the minimum value of $f(x, y, z)$. (Posed by Li Shenghong) | [
"First, prove that $f \\le \\frac{1}{7}$; when $x = y = z = \\frac{1}{3}$, we have $f = \\frac{1}{7}$.\nSince $f = \\sum \\frac{x(x+3y-1)}{1+x+3y} = 1 - 2\\sum \\frac{x}{1+x+3y}$, by Cauchy's inequality\n$$\n\\sum \\frac{x}{1+x+3y} \\ge \\frac{\\left(\\sum x\\right)^2}{\\sum x(1+x+3y)} = \\frac{1}{\\sum x(1+x+3y)},... | China | China Southeastern Mathematical Olympiad | [
"Algebra > Equations and Inequalities > Cauchy-Schwarz"
] | English | proof and answer | maximum 1/7, minimum 0 | |
0jja | Problem:
Carl is on a vertex of a regular pentagon. Every minute, he randomly selects an adjacent vertex (each with probability $\frac{1}{2}$) and walks along the edge to it. What is the probability that after 10 minutes, he ends up where he had started? | [
"Solution:\n\nAnswer: $\\frac{127}{512}$\n\nLet $A$ denote a clockwise move and $B$ denote a counterclockwise move. We want to have some combination of 10 $A$'s and $B$'s, with the number of $A$'s and the number of $B$'s differing by a multiple of 5. We have $\\binom{10}{0} + \\binom{10}{5} + \\binom{10}{10} = 254$... | United States | HMMT November 2014 | [
"Discrete Mathematics > Combinatorics > Algebraic properties of binomial coefficients"
] | null | final answer only | 127/512 | |
0e9m | Find all triples of real numbers $(x, y, z)$ that satisfy the system of equations
$$
\begin{aligned}
x^2 + y^2 + 4z^2 &= 6y - 4, \\
2xy - 4xz + 4yz &= y^2 + 5.
\end{aligned}
$$ | [
"Subtracting the second equality from the first we notice that the left side is a square of a trinomial. Indeed, we get\n$$\n(x - y + 2z)^2 = -y^2 + 6y - 9,\n$$\nwhich can be rearranged into\n$$\n(x - y + 2z)^2 + (y - 3)^2 = 0.\n$$\nSince $x$, $y$ and $z$ are real numbers the expressions in the brackets must be 0. ... | Slovenia | National Math Olympiad in Slovenia | [
"Algebra > Prealgebra / Basic Algebra > Simple Equations",
"Algebra > Intermediate Algebra > Quadratic functions"
] | null | proof and answer | (1, 3, 1) and (2, 3, 1/2) | |
0ghb | Find all positive integers $a$, $b$ and $c$ such that $ab$ is a square, and
$$
a + b + c - 3\sqrt[3]{abc} = 1.
$$
求所有正整數 $a$、$b$ 和 $c$,使得 $ab$ 為完全平方數且
$$
a + b + c - 3\sqrt[3]{abc} = 1.
$$ | [
"我們首先排除 $a = b$ 的可能性。注意到若 $a = b$,則對於所有質數 $p \\mid a$,由於 $p \\mid ab$ 且 $ab$ 為完全平方數,故 $p^2 \\mid ab$,這意味著 $p \\mid a+b-3\\sqrt[3]{abc}$。這表示 $p \\nmid c$,從而 $\\gcd(a, c) = 1$。又基於 $\\sqrt[3]{abc}$ 為整數,必須存在 $m, n \\in \\mathbb{N}$ 使得 $(a, b, c) = (m^3, m^3, n^3)$,從而\n$$\na + b + c - 3\\sqrt[3]{abc} = 2m^3 + n^3 - 3m^2... | Taiwan | 2023 數學奧林匹亞競賽第三階段選訓營 | [
"Algebra > Equations and Inequalities > QM-AM-GM-HM / Power Mean",
"Number Theory > Diophantine Equations > Techniques: modulo, size analysis, order analysis, inequalities"
] | Chinese (Traditional) | proof and answer | All triples are given by there exists a positive integer n such that {a, b} = {n^2, (n+1)^2} and c = n(n+1). | |
0a6z | Problem:
Let $a$, $b$, and $c$ be positive real numbers. Prove:
$$
\frac{a}{b} + \frac{b}{c} + \frac{c}{a} \leq \frac{a^{2}}{b^{2}} + \frac{b^{2}}{c^{2}} + \frac{c^{2}}{a^{2}}
$$ | [
"Solution:\nThe arithmetic-geometric inequality yields\n$$\n3 = 3 \\sqrt[3]{\\frac{a^{2}}{b^{2}} \\cdot \\frac{b^{2}}{c^{2}} \\cdot \\frac{c^{2}}{a^{2}}} \\leq \\frac{a^{2}}{b^{2}} + \\frac{b^{2}}{c^{2}} + \\frac{c^{2}}{a^{2}}\n$$\nor\n$$\n\\sqrt{3} \\leq \\sqrt{\\frac{a^{2}}{b^{2}} + \\frac{b^{2}}{c^{2}} + \\frac{... | Nordic Mathematical Olympiad | Nordic Mathematical Contest, NMC 1 | [
"Algebra > Equations and Inequalities > Cauchy-Schwarz",
"Algebra > Equations and Inequalities > QM-AM-GM-HM / Power Mean"
] | null | proof only | null | |
0cqb | Find all triples of prime numbers $(p, q, r)$ such that $pq \mid r^4 - 1$, $pr \mid q^4 - 1$, and $qr \mid p^4 - 1$.
Найдите все тройки простых чисел $p, q, r$ такие, что четвёртая степень любого из них, уменьшенная на 1, делится на произведение двух остальных. | [
"Ответ. $2, 3, 5$.\n\nЯсно, что любые два числа тройки различны (если $p = q$, то $p^4 - 1$ не делится на $q$). Пусть для определённости $p$ — наименьшее из чисел тройки. Нам известно, что число $p^4 - 1 = (p - 1)(p + 1)(p^2 + 1)$ делится на $qr$. Заметим, что $p - 1$ меньше любого из простых чисел $q$ и $r$, а зна... | Russia | Russian Mathematical Olympiad | [
"Number Theory > Divisibility / Factorization > Factorization techniques",
"Number Theory > Divisibility / Factorization > Greatest common divisors (gcd)"
] | English, Russian | proof and answer | 2, 3, 5 | |
09ir | Let $ABC$ be a triangle. Let $A_B$ denote the foot of the perpendicular line from $A$ to the exterior angle bisector of $B$, and let $A_C$ denote the foot of the perpendicular line from $A$ to the exterior angle bisector of $C$. The points $B_A, B_C, C_A, C_B$ are defined similarly. Prove that the hexagon $A_B A_C B_A ... | [] | Mongolia | Mongolian Mathematical Olympiad Round 2 | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Advanced Configurations > Isogonal/isotomic conjugates, barycentric coordinates",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing"
] | null | proof only | null | |
0j4r | Problem:
Let $f(x) = x^{2} + 6x + c$ for all real numbers $x$, where $c$ is some real number. For what values of $c$ does $f(f(x))$ have exactly 3 distinct real roots? | [
"Solution:\n\nSuppose $f$ has only one distinct root $r_{1}$. Then, if $x_{1}$ is a root of $f(f(x))$, it must be the case that $f(x_{1}) = r_{1}$. As a result, $f(f(x))$ would have at most two roots, thus not satisfying the problem condition. Hence $f$ has two distinct roots. Let them be $r_{1} \\neq r_{2}$.\n\nSi... | United States | Harvard-MIT Mathematics Tournament | [
"Algebra > Intermediate Algebra > Quadratic functions",
"Algebra > Algebraic Expressions > Polynomials > Polynomial operations"
] | null | proof and answer | (11 - sqrt(13))/2 | |
02iq | Problem:
Quais os valores de $x$ que satisfazem $\frac{1}{x-2}<4$?
(A) $x>\frac{3}{4}$
(B) $x>2$
(C) $\frac{3}{4}<x<2$
(D) $x<2$
(E) todos os valores de $x$. | [
"Solution:\n\nTemos: $\\frac{1}{x-2}<4 \\Rightarrow \\frac{1}{x-2}-4<0 \\Rightarrow \\frac{1-4(x-2)}{x-2}<0 \\Rightarrow \\frac{3-4x}{x-2}<0$.\n\nPara que uma fração seja negativa, o numerador e o denominador têm que ter sinais trocados.\n\n$1^\\circ$ caso: $3-4x>0$ e $x-2<0$.\n\n$3-4x>0 \\Rightarrow x<\\frac{3}{4}... | Brazil | Brazilian Mathematical Olympiad | [
"Algebra > Equations and Inequalities > Linear and quadratic inequalities",
"Algebra > Prealgebra / Basic Algebra > Fractions"
] | null | MCQ | C | |
05tt | Problem:
Soit $ABCD$ un parallélogramme. La bissectrice intérieure de l'angle $\widehat{BAC}$ coupe le segment $[BC]$ en $E$ tandis que sa bissectrice extérieure coupe la droite $(CD)$ en $F$. Soit $M$ le milieu du segment $[AE]$.
Démontrer que les droites $(EF)$ et $(BM)$ sont parallèles. | [
"Solution:\n\nSoit $G$ le point d'intersection des droites $(AB)$ et $(EF)$. Le problème revient à démontrer que $(MB)$ est une droite des milieux du triangle $AEG$, c'est-à-dire que $B$ est le milieu de $[AG]$.\n\nDe même, soit $H$ le point d'intersection des droites $(AE)$ et $(CD)$. L'homothétie de centre $E$ qu... | France | Préparation Olympique Française de Mathématiques | [
"Geometry > Plane Geometry > Transformations > Homothety",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing",
"Geometry > Plane Geometry > Analytic / Coordinate Methods > Vectors",
"Geometry > Plane Geometry > Advanced Configurations > Isogonal/isotomic conjugates, barycentric coordinates"
] | null | proof only | null | |
0dck | Let $ABC$ be a triangle with $A'$, $B'$, $C'$ as the midpoints of $BC$, $CA$, $AB$ respectively. The circle $(\omega_A)$ of center $A$ with sufficiently large radius cuts $B'C'$ at $X_1$, $X_2$. Define circles $(\omega_B)$, $(\omega_C)$ with $Y_1$, $Y_2$, $Z_1$, $Z_2$ similarly. Suppose that these circles have the same... | [
"Let $H$ be the orthocenter of $\\triangle ABC$. Since $AH \\perp X_1X_2$ and $AX_1 = AX_2$, then $HX_1 = HX_2$. Similarly, $HY_1 = HY_2$ and $HZ_1 = HZ_2$.\n\n\n\nDenote $R$ as the radius of the three circles $(\\omega_A)$, $(\\omega_B)$, $(\\omega_C)$. As $HB \\perp Y_1C'$, $HC \\perp Z_1... | Saudi Arabia | SAUDI ARABIAN MATHEMATICAL COMPETITIONS | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Miscellaneous > Distance chasing"
] | English | proof only | null | |
01ql | Points $K$, $L$, $M$ lie on the sides $BC$, $CA$, $AB$ of a triangle $ABC$, respectively, so that $AK$, $BL$, $CM$ meet at a common point. Let $r_1$, $r_2$, $r_3$, $r$ be the inradii of the triangles $ALM$, $BMK$, $CKL$, $ABC$, respectively.
Prove that $r_1 + r_2 + r_3 \ge r$ or $r_2 + r_3 \ge r$ or $r_1 \ge r$. | [
"2. See IMO-2014 Shortlist, Problem G2."
] | Belarus | SELECTION and TRAINING SESSION | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Concurrency and Collinearity > Ceva's theorem",
"Geometry > Plane Geometry > Circles > Tangents",
"Geometry > Plane Geometry > Geometric Inequa... | English | proof only | null | |
0h6w | Before 1995, in Football Championship of Ukraine in all leagues the team received 2 points for winning, 1 point for a draw and 0 points for a defeat. Since 1995, winning would give 3 points to the team, 1 point for a draw and 0 for a defeat. Football Federation has decided to transpose all the championships that were h... | [
"Team \"A\" is the winner when 2 points are calculated for a victory, and takes the last place when 3 points are calculated for a victory, while for the team \"B\" it is all the way around. Let the team \"A\" win $x$ matches and have $y$ draws. Team \"B\" will have $a$ wins and $b$ draws, respectively. Since there ... | Ukraine | UkraineMO | [
"Discrete Mathematics > Combinatorics > Coloring schemes, extremal arguments",
"Algebra > Equations and Inequalities > Linear and quadratic inequalities"
] | null | proof and answer | 12 | |
009g | Given several coins arranged in a row, a legal move is to take either the first or the last coin. In the initial arrangement there are $n$ coins of arbitrary denominations. Ana and Maria make moves in succession. Ana starts by making 2 moves, then Maria makes 1 move, and the same repeats until all coins are taken away:... | [
"The answer is yes for $n=2013$ and no for $n=2014$. More generally Ana can complete her task if $n=0 \\pmod{3}$ ($n \\ge 3$), and Maria can prevent her from doing so if $n \\equiv 1 \\pmod{3}$ ($n \\ge 4$).\nLet $n$ be a multiple of 3. Color the coins in 3 colors periodically: 1, 2, 3, 1, 2, 3, ..., 1, 2, 3. The c... | Argentina | NATIONAL XXX OMA | [
"Discrete Mathematics > Combinatorics > Games / greedy algorithms",
"Discrete Mathematics > Combinatorics > Coloring schemes, extremal arguments",
"Discrete Mathematics > Combinatorics > Invariants / monovariants"
] | null | proof and answer | 2013: yes; 2014: no | |
0bin | Let $n$ be a positive integer, let $S_n$ be the set of all permutations of the set $\{1, 2, \dots, n\}$, and, for each $\sigma$ in $S_n$, let $I(\sigma) = \{i: \sigma(i) \le i\}$. Evaluate the sum
$$
\sum_{\sigma \in S_n} \frac{1}{|I(\sigma)|} \sum_{i \in I(\sigma)} (i + \sigma(i)).
$$ | [
"Consider the involution of $S_n$ which sends a permutation $\\sigma$ to the permutation $\\sigma^*$ defined by $\\sigma^*(i) = j$ if and only if $\\sigma(n-j+1) = n-i+1$. Notice that, for each $\\sigma$ in $S_n$, the assignment $i \\mapsto n-\\sigma(i)+1$ defines a bijection from $I(\\sigma)$ to $I(\\sigma^*)$ who... | Romania | 65th NMO Selection Tests for BMO and IMO | [
"Discrete Mathematics > Combinatorics > Enumeration with symmetry",
"Discrete Mathematics > Combinatorics > Recursion, bijection"
] | null | proof and answer | (n+1)! | |
08xc | There are $24$ pieces each of two different kinds of cakes $A$ and $B$. All the cakes will be distributed among three people $X$, $Y$, $Z$. A method of distribution where a person may not receive any cake of a particular kind is allowed for consideration. How many different ways of distributing cakes are there in which... | [
"Let us denote by $a_X$, $a_Y$ and $a_Z$ the numbers of cakes of type $A$ received by $X$, $Y$ and $Z$ respectively, and by $b_X$, $b_Y$ and $b_Z$ the numbers of cakes of type $B$ received by $X$, $Y$ and $Z$, respectively. Then, they are non-negative integers and they satisfy $a_X + a_Y + a_Z = b_X + b_Y + b_Z = 2... | Japan | Japan 2013 Initial Round | [
"Discrete Mathematics > Combinatorics > Enumeration with symmetry"
] | English | proof and answer | 14017 | |
0h6o | Petro has to plant $8$ trees in a row: apple trees or oak trees. There is one restriction: there has to be no apple trees between any two oak trees. For example, such planting $AAOOAOAA$ or $OAOAAAAA$ are not allowed, and $AAOOAAAA$ is allowed. How many different plantings are possible? | [
"Obviously, all oaks have to be planted together as one group no matter where this group will be situated. Let us count how many oaks can possibly be.\n\nIf there are no oak trees, then the option of planting is only one.\n\nIf there are $k$ oaks, $1 \\leq k \\leq 8$, there are $9 - k$ options:\n\n$OOOAAAAA$, $AOOO... | Ukraine | UkraineMO | [
"Discrete Mathematics > Combinatorics"
] | null | final answer only | 37 | |
0k2g | Problem:
Let $a_{0}, a_{1}, \ldots$ and $b_{0}, b_{1}, \ldots$ be geometric sequences with common ratios $r_{a}$ and $r_{b}$, respectively, such that
$$
\sum_{i=0}^{\infty} a_{i}=\sum_{i=0}^{\infty} b_{i}=1 \quad \text{ and } \quad\left(\sum_{i=0}^{\infty} a_{i}^{2}\right)\left(\sum_{i=0}^{\infty} b_{i}^{2}\right)=\sum... | [
"Solution:\nAnswer: $\\frac{4}{3}$\nLet $a_{0}=a$ and $b_{0}=b$. From $\\sum_{i=0}^{\\infty} a_{i}=\\frac{a_{0}}{1-r_{a}}=1$ we have $a_{0}=1-r_{a}$ and similarly $b_{0}=1-r_{b}$. This means $\\sum_{i=0}^{\\infty} a_{i}^{2}=\\frac{a_{0}^{2}}{1-r_{a}^{2}}=\\frac{a^{2}}{\\left(1-r_{a}\\right)\\left(1+r_{a}\\right)}=\... | United States | HMMT November 2018 | [
"Algebra > Algebraic Expressions > Sequences and Series > Sums and products"
] | null | proof and answer | 4/3 | |
011h | Problem:
For every positive integer $n$, let
$$
x_{n} = \frac{(2n+1) \cdot (2n+3) \cdots (4n-1) \cdot (4n+1)}{2n \cdot (2n+2) \cdots (4n-2) \cdot 4n}
$$
Prove that $\frac{1}{4n} < x_{n} - \sqrt{2} < \frac{2}{n}$. | [
"Solution:\n\nSquaring both sides of the given equality and applying $x(x+2) \\leqslant (x+1)^{2}$ to the numerator of the obtained fraction and cancelling we have\n$$\nx_{n}^{2} \\leqslant \\frac{(2n+1) \\cdot (4n+1)}{(2n)^{2}} < 2 + \\frac{2}{n} .\n$$\nSimilarly (applying $x(x+2) \\leqslant (x+1)^{2}$ to the deno... | Baltic Way | Baltic Way | [
"Algebra > Equations and Inequalities > Linear and quadratic inequalities",
"Algebra > Algebraic Expressions > Sequences and Series > Sums and products"
] | null | proof only | null | |
093g | Problem:
An integer $n$ is called Silesian if there exist positive integers $a, b$ and $c$ such that
$$
n = \frac{a^{2} + b^{2} + c^{2}}{ab + bc + ca}
$$
a. Prove that there are infinitely many Silesian integers.
b. Prove that not every positive integer is Silesian. | [
"Solution:\n\na.\n\nAlternative 1:\nFirst, we try to find $k$ such that $k = \\frac{a^{2} + b^{2} + c^{2}}{ab + bc + ca}$ for some (not necessarily positive) integers $a, b, c$. In order to reduce the number of variables, we look for solutions satisfying $a + b = 1$. Substituting $b = 1 - a$ we find\n$$\nk = \\frac... | Middle European Mathematical Olympiad (MEMO) | Middle European Mathematical Olympiad | [
"Number Theory > Diophantine Equations > Techniques: modulo, size analysis, order analysis, inequalities",
"Number Theory > Diophantine Equations > Infinite descent / root flipping",
"Number Theory > Modular Arithmetic",
"Number Theory > Divisibility / Factorization > Greatest common divisors (gcd)",
"Algeb... | null | proof only | null | |
0bsu | If $A$ and $B$ are positive integers, then $\overline{AB}$ will denote the number obtained by writing, in order, the digits of $B$ after the digits of $A$. For instance, if $A = 193$ and $B = 2016$, then $\overline{AB} = 1932016$.
Prove that there are infinitely many perfect squares of the form $\overline{AB}$ in each ... | [
"a) $A = 4$ and $B = 9$ yields $\\overline{AB} = 49 = 7^2$. Adding an even number of zeroes we get infinitely many solutions: for $A = 4$ and $B = 9 \\cdot 10^{2n},\\ n \\in \\mathbb{N}$ we get $\\overline{AB} = (7 \\cdot 10^n)^2$.\n\nb) If $A = 8$ and $B = 10^{6n},\\ n \\in \\mathbb{N}$, then $\\overline{AB} = (9 ... | Romania | 67th Romanian Mathematical Olympiad | [
"Algebra > Prealgebra / Basic Algebra > Integers",
"Number Theory > Other"
] | English | proof only | null | |
0kw0 | Problem:
Five pairs of twins are randomly arranged around a circle. Then they perform zero or more swaps, where each swap switches the positions of two adjacent people. They want to reach a state where no one is adjacent to their twin. Compute the expected value of the smallest number of swaps needed to reach such a s... | [
"Solution:\n\nFirst, let's characterize the minimum number of swaps needed given a configuration. Each swap destroys $0$, $1$, or $2$ adjacent pairs. If at least one pair is destroyed, no other adjacent pairs can be formed. Therefore, we only care about the count of adjacent pairs and should never create any new on... | United States | HMMT February 2023 | [
"Discrete Mathematics > Combinatorics > Expected values",
"Discrete Mathematics > Combinatorics > Inclusion-exclusion"
] | null | proof and answer | 926/945 | |
0axo | Problem:
Suppose $a$, $b$, and $c$ are the sides of a triangle opposite angles $\alpha$, $\beta$, and $\gamma$ respectively. If $\cos \beta < 0$ and $\cos \alpha < \cos \gamma$, arrange $a$, $b$, and $c$ in increasing order. | [
"Solution:\n$\\beta$ must be obtuse and therefore the largest angle, and so $b$ is the longest side. As for $a$ and $c$, since $\\alpha$ and $\\gamma$ must both be acute, cos is decreasing and thus $\\alpha > \\gamma$, so $a > c$."
] | Philippines | Philippine Mathematical Olympiad | [
"Geometry > Plane Geometry > Triangles > Triangle trigonometry"
] | null | final answer only | c < a < b | |
0hev | Eight children, who did not know each other, came to the dance class. To introduce them to each other, teacher decided to choose four children each minute and let them dance in a circle. During this minute, each of the children in a circle will get to know a neighbor on the left and on the right. What is the minimal nu... | [
"Consider any child from this group. They need to get to know seven other children, and participating once in a dancing circle they meet maximum two new acquaintances. Thus, each child should participate in at least four dancing circles. In each dancing circle, there are no more than four children participating. Th... | Ukraine | 60th Ukrainian National Mathematical Olympiad | [
"Discrete Mathematics > Combinatorics > Counting two ways",
"Discrete Mathematics > Combinatorics > Coloring schemes, extremal arguments"
] | null | proof and answer | 8 | |
0ih1 | Problem:
Every second, Andrea writes down a random digit uniformly chosen from the set $\{1,2,3,4\}$. She stops when the last two numbers she has written sum to a prime number. What is the probability that the last number she writes down is 1? | [
"Solution:\n\nLet $p_{n}$ be the probability that the last number she writes down is 1 when the first number she writes down is $n$.\n\nSuppose she starts by writing 2 or 4. Then she can continue writing either 2 or 4, but the first time she writes 1 or 3, she stops. Therefore $p_{2} = p_{4} = \\frac{1}{2}$.\n\nSup... | United States | Harvard-MIT Mathematics Tournament | [
"Discrete Mathematics > Combinatorics > Recursion, bijection"
] | null | proof and answer | 15/44 | |
0d5a | Find all functions $f: \mathbb{R} \rightarrow \mathbb{R}$ that satisfy
$$
f\left(x+y^{2}-f(y)\right)=f(x)
$$
for all $x, y \in \mathbb{R}$. | [
"Notice that the function $f$, defined by $f(x)=x^{2}$ for all $x \\in \\mathbb{R}$, is a solution of the equation.\n\nAssume that there exists $a \\in \\mathbb{R}$ such that $f(a) \\neq a^{2}$ and let $b=a^{2}-f(a) \\neq 0$. Then for all $x \\in \\mathbb{R}$ we have $f(x+b)=f(x)$. Therefore, for all $x, y \\in \\m... | Saudi Arabia | SAMC 2015 | [
"Algebra > Algebraic Expressions > Functional Equations > Existential quantifiers"
] | English, Arabic | proof and answer | All constant functions f(x) = c for any real constant c, and the function f(x) = x^2. | |
0l1c | Each of 27 bricks (right rectangular prisms) has dimensions $a \times b \times c$, where $a$, $b$, and $c$ are pairwise relatively prime positive integers. These bricks are arranged to form a $3 \times 3 \times 3$ block, as shown on the left below. A 28th brick with the same dimensions is introduced, and these bricks a... | [
"Without loss of generality, assume $a < b < c$. Comparing the figures and considering the change in orientation gives rise to the equations $3a + 1 = 2b$, $3b + 1 = 2c$, and $3c + 1 = 7a$. To solve this system of linear equations, use the first two equations to write $a$ and $c$ in terms of $b$, namely $a = \\frac... | United States | AMC 10 B | [
"Algebra > Prealgebra / Basic Algebra > Simple Equations",
"Geometry > Solid Geometry > 3D Shapes"
] | null | MCQ | E | |
0b45 | Problem:
Let $I$ be the center of the incircle of triangle $ABC$. Suppose that this incircle has radius $3$, and that $AI = 5$. If the area of the triangle is $2022$, what is the length of $BC$?
(a) 670
(b) 672
(c) 1340
(d) 1344 | [
"Solution:\n\nLet $r$ be the inradius, $r = 3$. Let $S$ be the area, $S = 2022$. Let $a = BC$.\n\nRecall that $S = r \\cdot s$, where $s$ is the semiperimeter. So:\n$$\ns = \\frac{S}{r} = \\frac{2022}{3} = 674\n$$\n\nLet $AI$ be the distance from $A$ to the incenter $I$. There is a formula:\n$$\nAI^2 = \\frac{bc}{(... | Philippines | 24th Philippine Mathematical Olympiad | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle"
] | null | MCQ | a | |
0fr7 | Problem:
Determinar todos los valores reales de $(x, y, z)$ para los cuales
$$
\begin{array}{cccc}
x+y+z & = & 1 \\
x^{2} y+y^{2} z+z^{2} x & = & x y^{2}+y z^{2}+z x^{2} \\
x^{3}+y^{2}+z & = & y^{3}+z^{2}+x
\end{array}
$$ | [
"Solution:\nLa segunda ecuación la podemos reescribir como\n$$\n(x-y)(y-z)(z-x)=0\n$$\nAhora, dado que la tercera ecuación no es simétrica, vamos a distinguir 3 casos diferentes:\n\na. Si $x=y$, la tercera ecuación queda\n$$\nx^{2}+z=z^{2}+x\n$$\no alternativamente\n$$\n(x-z)(x+z-1)=0\n$$\nPor tanto, de las dos últ... | Spain | FASE LOCAL DE LA OLIMPIADA MATEMÁTICA ESPAÑOLA. | [
"Algebra > Algebraic Expressions > Polynomials > Polynomial operations",
"Algebra > Algebraic Expressions > Polynomials > Symmetric functions",
"Algebra > Prealgebra / Basic Algebra > Simple Equations"
] | null | proof and answer | (1/3, 1/3, 1/3), (0, 0, 1), (0, 1, 0), (2/3, -1/3, 2/3), (1, 0, 0), (-1, 1, 1) | |
0doo | Find the sum
$$
\sum_{k \in A} \frac{1}{k-1}
$$
if $A = \{m^n : m, n \in \mathbb{Z}, m, n \ge 2\}$. | [
"Answer: the sum is equal $1$.\nThis can be seen as follows:\n$$\n\\sum_{k \\in A} \\frac{1}{k-1} = \\sum_{k \\in A} \\left( \\frac{1}{k} \\cdot \\frac{1}{1-1/k} \\right) = \\sum_{k \\in A} \\sum_{i \\ge 1} \\frac{1}{k^i}\n$$\n**Proposition:** For $x \\in \\mathbb{Z}$ the sets $\\{(m,n) : x = m^n; m, n \\in \\mathb... | Silk Road Mathematics Competition | Silk Road Mathematics Competition | [
"Algebra > Algebraic Expressions > Sequences and Series > Sums and products",
"Algebra > Algebraic Expressions > Sequences and Series > Telescoping series",
"Number Theory > Divisibility / Factorization > Greatest common divisors (gcd)",
"Number Theory > Number-Theoretic Functions > τ (number of divisors)",
... | English | proof and answer | 1 | |
07xz | Prove that
$$
2 \sum_{k=0}^{n} \binom{2n}{k} = \binom{2n}{n} + 2^{2n}, \ n = 1, 2, \dots
$$
Prove also that
$$
2 \sum_{k=0}^{n} \binom{2n}{k} (-1)^k = \binom{2n}{n} (-1)^n, \ n = 1, 2, \dots
$$ | [
"By the binomial expansion\n$$\n(1 + t)^m = \\sum_{k=0}^{m} \\binom{m}{k} t^k,\n$$\nfor any positive integer $m$ and any $t$. In particular, taking $t = 1$ and $m = 2n$, and using $\\binom{2n}{k} = \\binom{2n}{2n-k}$ we have\n$$\n\\begin{aligned}\n2^{2n} &= \\sum_{k=0}^{2n} \\binom{2n}{k} = \\sum_{k=0}^{n} \\binom{... | Ireland | IRL_ABooklet_2025 | [
"Algebra > Algebraic Expressions > Polynomials > Polynomial operations",
"Discrete Mathematics > Combinatorics > Algebraic properties of binomial coefficients",
"Algebra > Algebraic Expressions > Sequences and Series > Sums and products"
] | null | proof only | null | |
0dms | Problem:
Нека је $O$ центар описане кружнице $\triangle ABC$. Права кроз $O$ сече странице $CA$ и $CB$ у тачкама $D$ и $E$, редом, и описану кружницу $\triangle ABO$ у тачки $P$ унутар троугла (различитој од $O$). Тачка $Q$ на страници $AB$ је таква да је $\frac{AQ}{QB} = \frac{DP}{PE}$. Доказати да је $\angle APQ = 2... | [
"Solution:\n\nНека је $X$ тачка на полуправој $AP$ таква да је $EX \\parallel AC$. По Талесовој теореми је $AP : PX = DP : PE = AQ : QB$, одакле следи $BX \\parallel QP$.\n\nПрава $PE$ је спољашња симетрала угла $APB$ и полови угао $BPX$. Такође, пошто је $\\angle BEX = 180^{\\circ} - \\angle ACB$ и $\\angle BPX = ... | Serbia | Serbian Mathematical Olympiad | [
"Geometry > Plane Geometry > Miscellaneous > Angle chasing",
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Analytic / Coordinate Methods > Trigonometry",
"Geometry > Plane Geometry > Triang... | null | proof only | null | |
07mg | Find all polynomials $f(x) = x^3 + bx^2 + cx + d$, where $b, c, d$ are real numbers, such that $f(x^2 - 2) = -f(-x)f(x)$. | [
"The 'obvious' approach is to equate coefficients of powers of $x$ in $f(x^2 - 2)$ and $-f(-x)f(x)$ to get:\n$$\nb - 6 = 2c - b^2, \\quad -2bd + c^2 = 12 - 4b + c, \\quad -d^2 = -8 + 4b - 2c + d. \\quad (3)\n$$\nIt is possible, albeit difficult, to solve these equations directly. For example, if $b=0$, we get $c = ... | Ireland | Irish Mathematical Olympiad | [
"Algebra > Algebraic Expressions > Functional Equations",
"Algebra > Algebraic Expressions > Polynomials > Vieta's formulas",
"Algebra > Algebraic Expressions > Polynomials > Polynomial operations"
] | null | proof and answer | x^3 - 3x + 1; x^3 - 3x - 2; x^3 + x^2 - 2x - 1; x^3 + 2x^2 - 1; x^3 - x^2 - 3x + 2; x^3 - 3x^2 + 4; x^3 + 3x^2 + 3x + 1; x^3 - 6x^2 + 12x - 8 | |
0cn1 | In the plane, all the points with integer coordinates $(x, y)$ such that $x^2 + y^2 \le 10^{10}$, are marked. Two players $A$ and $B$ play the following game. They move turn by turn. On the first move, $A$ places a token in some marked point and erases this point. After that, by each move the next player moves the toke... | [
"Первый игрок выигрывает.\n\nДокажем более общее утверждение: *Пусть игра с теми же правилами происходит на конечном множестве точек $S$, которое содержит точку $O(0,0)$ и переходит в себя при повороте на $90^\\circ$. Тогда в этой игре выигрывает первый игрок. (Ясно, что множество точек из условия удовлетворяет эти... | Russia | Russian mathematical olympiad | [
"Discrete Mathematics > Combinatorics > Games / greedy algorithms",
"Discrete Mathematics > Combinatorics > Induction / smoothing",
"Geometry > Plane Geometry > Transformations > Rotation"
] | English; Russian | proof and answer | Player A | |
0ecw | The circles $\mathcal{K}_1$ and $\mathcal{K}_2$ in the figure are the circumcircle and incircle of the equilateral triangle $ABC$. A square $DEFG$ is inscribed in the circle $\mathcal{K}_2$ so that the point $D$ lies on the side $AB$. The circles $\mathcal{K}_3$ and $\mathcal{K}_4$ are of the same size and touch each o... | [
"\n\nDenote by $r_1, r_2, r_3$, and $r_4$ the radii of the circles $K_1, K_2, K_3$, and $K_4$. We know that $r_3 = r_4$. Since the triangle $ABC$ is equilateral the circles $K_1$ and $K_2$ have a common center which we denote by $S$. The triangle $BSD$ is a half of ... | Slovenia | National Math Olympiad 2015 – First Round | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Circles > Tangents",
"Geometry > Plane Geometry > Quadrilaterals > Inscribed/circumscribed quadrilaterals",
"Geometry > Plane Geometry > Miscellaneous > Dis... | null | proof and answer | 2 + 2*sqrt(2) | |
06is | Let $n$ be a positive integer. If the two numbers $(n+1)(2n+15)$ and $n(n+5)$ have exactly the same prime factors, find the greatest possible value of $n$. | [
"Let $p$ be any prime factor of $n+1$. Then $p$ is a prime factor of $(n+1)(2n+15)$ and hence of $n(n + 5)$ as well. Since $n(n + 5) = (n + 1)(n + 4) - 4$, we conclude that $p$ divides $4$, and so $p$ can only be $2$. In the same way, we find that the only possible prime divisors of $n+5$ are $2$ and $5$.\n\nLet $n... | Hong Kong | Hong Kong Preliminary Selection Contest | [
"Number Theory > Divisibility / Factorization > Factorization techniques",
"Number Theory > Diophantine Equations > Techniques: modulo, size analysis, order analysis, inequalities"
] | English | proof and answer | 15 | |
017l | Let $x_1, x_2, \dots, x_n$ ($n \ge 2$) be real numbers greater than $1$. Suppose that $|x_i - x_{i+1}| < 1$ for $i = 1, 2, \dots, n-1$. Prove that
$$
\frac{x_1}{x_2} + \frac{x_2}{x_3} + \dots + \frac{x_{n-1}}{x_n} + \frac{x_n}{x_1} < 2n - 1
$$ | [
"The proof is by induction on $n$.\n\nWe establish first the base case $n = 2$. Suppose that $x_1 > 1$, $x_2 > 1$, $|x_1 - x_2| < 1$ and moreover $x_1 \\le x_2$. Then\n$$\n\\frac{x_1}{x_2} + \\frac{x_2}{x_1} \\le 1 + \\frac{x_2}{x_1} < 1 + \\frac{x_1+1}{x_1} = 2 + \\frac{1}{x_1} < 2+1=2 \\cdot 2-1.\n$$\n\nNow we pr... | Baltic Way | BALTIC WAY | [
"Algebra > Equations and Inequalities",
"Discrete Mathematics > Combinatorics > Induction / smoothing"
] | null | proof only | null | |
00ni | Let $\alpha$ be a real number.
Determine all functions $f : \mathbb{R} \to \mathbb{R}$ satisfying
$$
f(f(x) + y) = f(x^2 - y) + \alpha f(x)y
$$
for all $x, y \in \mathbb{R}$. | [
"First, we set $y = (x^2 - f(x))/2$ which gives $\\alpha f(x)(x^2 - f(x))/2 = 0$. Now, we distinguish the cases $\\alpha \\ne 0$ and $\\alpha = 0$.\n\na. In the case $\\alpha \\ne 0$, this equation implies $f(x) = 0$ or $f(x) = x^2$ for each $x$ separately.\nIn particular, $f(0) = 0$.\n\n◦ It is easily verified tha... | Austria | Austrian Mathematical Olympiad | [
"Algebra > Algebraic Expressions > Functional Equations > Existential quantifiers"
] | English | proof and answer | All solutions are:
- For α = 0: all constant functions f(x) = c for any real c, and f(x) = −x^2.
- For α = 4: f(x) ≡ 0 and f(x) = x^2.
- For all other α (α ≠ 0 and α ≠ 4): only f(x) ≡ 0. | |
009q | Twenty undistinguishable coins are arranged in a row. One of them weighs $9$ grams and the next coin to the right weighs $11$ grams. The remaining $18$ coins have weight $10$ grams each. Find the $11$ gram coin with $3$ weightings on a two-pan balance without weights. | [
"On the first attempt compare two groups of $9$ coins each: $G_1 = 1,3,5,7,9,11,13,15,17$ and $G_2 = 2,4,6,8,10,12,14,16,18$. Note that the $9$ grams coin $A$ and the $11$ grams coin $B$ cannot be on the same pan as their positions are consecutive, hence of different parity.\n\nIf there is equilibrium we claim that... | Argentina | NATIONAL XXX OMA | [
"Discrete Mathematics > Algorithms",
"Discrete Mathematics > Logic"
] | null | proof only | null | |
0auc | Problem:
Find the maximum value of
$$
(1-x)(2-y)(3-z)\left(x+\frac{y}{2}+\frac{z}{3}\right)
$$
where $x<1$, $y<2$, $z<3$, and $x+\frac{y}{2}+\frac{z}{3}>0$. | [] | Philippines | 17th Philippine Mathematical Olympiad Area Stage | [
"Algebra > Equations and Inequalities > QM-AM-GM-HM / Power Mean"
] | null | proof and answer | 243/128 | |
0570 | There are the same number of boys and girls in a class. It is known that $60\%$ of pupils do sports and $\frac{5}{9}$ of pupils doing sports are boys. It is also known that $\frac{1}{3}$ of pupils doing sports go to math club and $\frac{2}{15}$ of girls neither do sports nor go to math club. On the other hand, $\frac{2... | [
"There are $\\frac{3}{5} \\cdot \\frac{1}{3} = \\frac{1}{5}$ of pupils who both do sports and go to math club, whereas $\\frac{1}{2} \\cdot \\frac{2}{15} = \\frac{1}{15}$ of pupils are boys who both do sports and go to math club. Thus $\\frac{1}{5} - \\frac{1}{15} = \\frac{2}{15}$ of pupils are girls who both do sp... | Estonia | Final Round of National Olympiad | [
"Algebra > Prealgebra / Basic Algebra > Fractions",
"Algebra > Prealgebra / Basic Algebra > Simple Equations"
] | null | final answer only | 60% | |
08a8 | Problem:
Sia $ABC$ un triangolo con i lati $AB$, $CA$ e $BC$ di lunghezza rispettivamente $17$, $25$ e $26$. Siano $X$ e $Y$ le intersezioni della parallela ad $AB$ passante per $C$ con le bisettrici di $C\widehat{A}B$ e di $A\widehat{B}C$ rispettivamente. Quanto vale l'area del trapezio $ABXY$?
(A) 816
(B) $338(1+\s... | [
"Solution:\n\nLa risposta è (A). Sia $I$ l'incentro del triangolo $ABC$; allora i triangoli $AIB$ e $XIY$ sono simili per via del parallelismo fra le rette $AB$ e $XY$. Sia $h$ l'altezza del trapezio $ABXY$, ovvero l'altezza del triangolo $ABC$ relativa alla base $AB$; l'altezza del triangolo $AIB$ relativa ad $AB$... | Italy | Progetto Olimpiadi della Matematica - Gara di Febbraio | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Transformations > Homothety",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing"
] | null | MCQ | A | |
0664 | If the number $3\nu + 1$, where $\nu$ is integer, is a multiple of $7$, find the possible remainders of the following divisions:
(a) of $\nu$ with divisor $7$,
(b) of $\nu^m$ with divisor $7$, for all values of the positive integer $m$, $m \ge 2$. | [
"(a) Let $3\\nu + 1 = 7\\kappa$, where $\\nu, \\kappa \\in \\mathbb{Z}$. The integer $\\nu$ is of the form $\\nu = 7\\rho + \\upsilon$, where $\\upsilon \\in \\{0,1,2,3,4,5,6\\}$ and $\\rho \\in \\mathbb{Z}$. Then we have:\n$$\n3(7\\rho + \\upsilon) + 1 = 7\\kappa \\Leftrightarrow 21\\rho + 3\\upsilon + 1 = 7\\kapp... | Greece | 28th Hellenic Mathematical Olympiad | [
"Number Theory > Modular Arithmetic > Inverses mod n",
"Number Theory > Residues and Primitive Roots > Multiplicative order",
"Algebra > Algebraic Expressions > Polynomials > Polynomial operations"
] | English | proof and answer | (a) 2; (b) 1, 2, or 4 | |
0k1l | Problem:
On a computer screen is the single character $a$. The computer has two keys: $c$ (copy) and $p$ (paste), which may be pressed in any sequence.
Pressing $p$ increases the number of $a$'s on screen by the number that were there the last time $c$ was pressed. $c$ doesn't change the number of $a$'s on screen. De... | [
"Solution:\n\nThe first keystroke must be $c$ and the last keystroke must be $p$. If there are $k$ $c$'s pressed in total, let $n_{i}$ denote one more than the number of $p$'s pressed immediately following the $i$'th $c$, for $1 \\leq i \\leq k$.\n\nThen, we have that the total number of keystrokes is\n$$\ns := \\s... | United States | HMMT November 2018 | [
"Algebra > Equations and Inequalities > QM-AM-GM-HM / Power Mean",
"Algebra > Equations and Inequalities > Combinatorial optimization"
] | null | proof and answer | 21 | |
088g | Problem:
Quante sono le soluzioni reali distinte dell'equazione $x^{6}+2 x^{5}+2 x^{4}+2 x^{3}+2 x^{2}+2 x+1=0$ ?
(A) 0
(B) 1
(C) 2
(D) 4
(E) 6 . | [
"Solution:\n\nLa risposta è **(B)**. Osserviamo innanzitutto che il polinomio del testo si può scrivere come $(1+2 x+2 x^{2}+x^{3})+(x^{3}+2 x^{4}+2 x^{5}+x^{6}) = (1+2 x+2 x^{2}+x^{3}) + x^{3}(1+2 x+2 x^{2}+x^{3}) = (1+x^{3})(1+2 x+2 x^{2}+x^{3})$.\n\nRiconoscendo poi che si può ulteriormente scrivere $1+2 x+2 x^{... | Italy | Progetto Olimpiadi di Matematica | [
"Algebra > Algebraic Expressions > Polynomials > Polynomial operations",
"Algebra > Intermediate Algebra > Quadratic functions",
"Algebra > Equations and Inequalities > Linear and quadratic inequalities"
] | null | MCQ | B | |
08e4 | Problem:
Sia $ABC$ un triangolo acutangolo con $AB = AC$. Sia $D$ il piede dell'altezza uscente da $C$, sia $M$ il punto medio di $AC$, e sia $E$ la seconda intersezione tra il lato $BC$ e la circonferenza circoscritta al triangolo $CDM$.
Dimostrare che le rette $AE$, $BM$ e $CD$ passano per uno stesso punto se e solo... | [] | Italy | XXXVI Olimpiade Italiana di Matematica | [
"Geometry > Plane Geometry > Concurrency and Collinearity > Ceva's theorem",
"Geometry > Plane Geometry > Quadrilaterals > Cyclic quadrilaterals",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing",
"Geometry > Plane Geometry > Analytic / Coordinate Methods > Trigonometry"
] | null | proof only | null | |
028p | Problem:
A sequência $\{a, b, c\}$ - A lei de formação da sequência $10, a, 30, b, c, \ldots$ é: cada termo, começando com o $30$, é o dobro da soma dos dois termos imediatamente anteriores. Qual o valor de $c$? | [
"Solution:\n\nSabemos que $30 = 2(10 + a)$, logo $a = 5$.\n\n$$\nb = 2(30 + a) = 2(30 + 5) = 70\n$$\n\ne\n$$\nc = 2(b + 30) = 2(70 + 30) = 200\n$$"
] | Brazil | null | [
"Algebra > Algebraic Expressions > Sequences and Series > Recurrence relations",
"Algebra > Prealgebra / Basic Algebra > Simple Equations"
] | null | final answer only | 200 | |
0lbm | Find all integers $x, y$ such that
$$
x(x^{999} - 1) = (x - 1)y(y + 2).
$$ | [] | Vietnam | Vietnamese Mathematical Competitions | [
"Number Theory > Diophantine Equations > Techniques: modulo, size analysis, order analysis, inequalities",
"Number Theory > Divisibility / Factorization > Factorization techniques"
] | null | proof and answer | All integer solutions are: (x, y) = (1, any integer y); (x, y) = (0, 0); (x, y) = (0, −2); (x, y) = (−1, −1). | |
0juh | Problem:
Consider a three-person game involving the following three types of fair six-sided dice.
- Dice of type $A$ have faces labelled $2,2,4,4,9,9$.
- Dice of type $B$ have faces labelled $1,1,6,6,8,8$.
- Dice of type $C$ have faces labelled $3,3,5,5,7,7$.
All three players simultaneously choose a die (more than on... | [
"Solution:\n\nShort version: third player doesn't matter; against $1$ opponent, by symmetry, you'd both play the same strategy. Type $A$ beats $B$, $B$ beats $C$, and $C$ beats $A$ all with probability $5/9$. It can be determined that choosing each die with probability $1/3$ is the best strategy. Then, whatever you... | United States | HMMT February | [
"Discrete Mathematics > Combinatorics > Expected values",
"Discrete Mathematics > Combinatorics > Games / greedy algorithms"
] | null | proof and answer | 8/9 | |
09l4 | A convex polygon has exactly $2023$ obtuse angles. Determine the maximum possible number of angles that this polygon can have. | [] | Mongolia | Mongolian Mathematical Olympiad | [
"Geometry > Plane Geometry > Miscellaneous > Angle chasing",
"Geometry > Plane Geometry > Geometric Inequalities > Optimization in geometry"
] | English | proof and answer | 2026 | |
0emg | Given a regular hexagon, a point inside is chosen and lines to each vertex of the hexagon are drawn, dividing it into six triangles. If the triangles are alternately shaded grey and white, show that the area of the grey triangles is the same as the area of the white triangles. | [
"\n\nExpand the hexagon to make a big equilateral triangle, and drop perpendiculars from the point inside to the sides of the triangle. The area of the unshaded region of the hexagon, which is three triangles of equal bases, is equal to $\\frac{1}{2}$ side length multiplied by the sum of th... | South Africa | South-Afrika 2011-2013 | [
"Geometry > Plane Geometry > Miscellaneous > Distance chasing",
"Geometry > Plane Geometry > Miscellaneous > Constructions and loci"
] | null | proof only | null | |
0b2s | Problem:
Let $n$ be a positive integer. Show that there exists a one-to-one function $\sigma:\{1,2, \ldots, n\} \rightarrow \{1,2, \ldots, n\}$ such that
$$
\sum_{k=1}^{n} \frac{k}{(k+\sigma(k))^{2}}<\frac{1}{2}
$$ | [
"Solution:\nIt suffices to produce one such function. For this, consider the function $\\sigma(k) = n+1-k$. Then note that $\\sigma$ is one-to-one, since for every $a$ and $b$,\n$$\n\\sigma(a) = \\sigma(b) \\Rightarrow n+1-a = n+1-b \\Rightarrow a = b\n$$\nIn this case,\n$$\n\\begin{aligned}\n\\sum_{k=1}^{n} \\frac... | Philippines | 23rd Philippine Mathematical Olympiad | [
"Algebra > Algebraic Expressions > Sequences and Series > Sums and products",
"Algebra > Equations and Inequalities > Linear and quadratic inequalities",
"Algebra > Abstract Algebra > Permutations / basic group theory"
] | null | proof only | null | |
03or | Before The World Cup tournament, the football coach of $F$ country will let seven players, $A_1, A_2, \dots, A_7$, join three training matches (90 minutes each) in order to assess them. Suppose, at any moment during a match, one and only one of them enters the field, and the total time (which is measured in minutes) on... | [
"Suppose that $x_i$ ($i = 1, 2, \\dots, 7$) minutes is the time for $i$-th player on the field. Now, the problem is to find the number of solution groups of positive integers for the following equation:\n$$\nx_1 + x_2 + \\cdots + x_7 = 270\n$$\nwhen the conditions $7 \\mid x_i$ ($i = 1, 2, 3, 4$) and $13 \\mid x_j$... | China | China Mathematical Competition (Extra Test) | [
"Discrete Mathematics > Combinatorics > Recursion, bijection",
"Number Theory > Diophantine Equations > Techniques: modulo, size analysis, order analysis, inequalities"
] | English | final answer only | 42244 | |
07qb | Suppose $a$, $b$, $c$ are real numbers such that $abc \neq 0$. Determine $x$, $y$, $z$ in terms of $a$, $b$, $c$ such that
$$
bz + cy = a, \quad cx + az = b, \quad ay + bx = c.
$$
Prove also that
$$
\frac{1-x^2}{a^2} = \frac{1-y^2}{b^2} = \frac{1-z^2}{c^2}.
$$ | [
"Multiply the first equation by $a$, the second by $b$ and the third by $c$. Add the difference between the first and second of the resulting equations to the third one, thereby obtaining the following one:\n$$\n2cay = c^2 + a^2 - b^2.\n$$\nSince $ca \\neq 0$, it follows that\n$$\ny = \\frac{c^2 + a^2 - b^2}{2ca}.\... | Ireland | Irish Mathematical Olympiad | [
"Algebra > Prealgebra / Basic Algebra > Simple Equations",
"Algebra > Algebraic Expressions > Polynomials > Symmetric functions"
] | null | proof and answer | x = (b^2 + c^2 − a^2) / (2bc), y = (c^2 + a^2 − b^2) / (2ca), z = (a^2 + b^2 − c^2) / (2ab), and (1 − x^2)/a^2 = (1 − y^2)/b^2 = (1 − z^2)/c^2 = 4s(s − a)(s − b)(s − c) / (a^2 b^2 c^2), where s = (a + b + c)/2. | |
0dn6 | Problem:
Дат је природан број $k$. Нека је $f: \mathbb{Z} \rightarrow \mathbb{Z}$ бијекција таква да за свака два цела броја $i$ и $j$ за које је $|i-j| \leqslant k$ важи $|f(i)-f(j)| \leqslant k$. Доказати да за све $i, j \in \mathbb{Z}$ важи
$$
|f(i)-f(j)|=|i-j|
$$ | [
"Solution:\n\nЗа $k=1$ тврђење је тривијално. Нека је зато $k>2$. Интервалом дужине $k$ зовемо скуп облика $\\{x, x+1, \\ldots, x+k\\}, x \\in \\mathbb{Z}$. Два цела броја $x$ и $y$ ће бити узастопна ако и само ако постоје интервали $I_{1}$ и $I_{2}$ дужине $k$ за које је $I_{1} \\cap I_{2}=\\{x, y\\}$. Међутим, по... | Serbia | Serbian Mathematical Olympiad | [
"Algebra > Algebraic Expressions > Functional Equations > Injectivity / surjectivity",
"Discrete Mathematics > Combinatorics > Induction / smoothing"
] | null | proof only | null | |
04ok | Ana and Vanja are standing together next to a railway, waiting for the train to pass. The train drives at constant speed. At the moment the front end of the train passes them, Ana starts walking at constant speed in the same direction as the train is going, and Vanja starts walking at the same speed in the opposite dir... | [
"Note that Ana walked $45 - 30 = 15$ metres more than Vanja, and while Ana was walking these $15$ metres, the train travelled $45 + 30 = 75$ metres.\nTherefore, the speed of the train is $\\frac{75}{15} = 5$ times greater than the walking speed.\nAlso note that while Vanja walked $30$ metres, the train travelled $3... | Croatia | Croatian Mathematical Society Competitions | [
"Algebra > Prealgebra / Basic Algebra > Simple Equations"
] | English | proof and answer | 180 metres | |
07mn | Let $ABC$ be a triangle. The circle of centre $A$ and tangent to the side $BC$ intersects the circle of centre $C$ and tangent to $AB$ at two points $M$ and $N$. Show that $M$, $N$ and $B$ are collinear if and only if $|AB| = |BC|$. | [
"Let $AD$, $BE$ and $CF$ be the altitudes of the triangle $ABC$ so that points $D$, $E$ and $F$ are on the sides $BC$, $CA$ and $AB$ respectively. Since the triangles $AMC$ and $ANC$ are congruent, $MN$ is perpendicular to $AC$.\n\nFirst, suppose that $B$, $M$ and $N$ are collinear. Then $E$ is the intersection poi... | Ireland | Irish Mathematical Olympiad | [
"Geometry > Plane Geometry > Circles > Tangents",
"Geometry > Plane Geometry > Concurrency and Collinearity",
"Geometry > Plane Geometry > Miscellaneous > Distance chasing",
"Geometry > Plane Geometry > Miscellaneous > Constructions and loci"
] | null | proof only | null | |
0baf | The sequence $(a_n)_{n \ge 1}$ of real numbers is such that the sequence $(x_n)_{n \ge 1}$ defined by $x_n = \max\{a_n, a_{n+1}, a_{n+2}\}$ is convergent and the sequence $(y_n)_{n \ge 1}$ defined by $y_n = a_{n+1} - a_n$ has limit $0$. Prove that the sequence $(a_n)_n$ is convergent. | [
"Let $L = \\lim_{n \\to \\infty} x_n$. Since $x_n = \\max\\{a_n, a_{n+1}, a_{n+2}\\}$, for every $n$, $a_n \\le x_n$, $a_{n+1} \\le x_n$, $a_{n+2} \\le x_n$.\n\nLet $\\varepsilon > 0$. Since $x_n \\to L$, there exists $N_1$ such that for all $n \\ge N_1$, $|x_n - L| < \\varepsilon/2$, i.e., $L - \\varepsilon/2 < x_... | Romania | SHORTLISTED PROBLEMS FOR THE 62nd NMO | [
"Algebra > Algebraic Expressions > Sequences and Series"
] | null | proof only | null | |
09og | Each cell $(i, j)$ of a $2n \times 2n$ grid is filled with the number $2n(i-1)+j$.
A total of $2n^2$ cells are selected such that exactly $n$ cells are chosen from each row and exactly $n$ cells from each column. Prove that the sum of the numbers in the selected cells is equal to the sum of the numbers in the unselecte... | [] | Mongolia | MMO2025 Round 3 | [
"Discrete Mathematics > Combinatorics > Counting two ways"
] | English | proof only | null | |
0cp3 | Each of 1000 dwarves wears a hat, its outer surface being blue, and its inner surface being red (or vice versa). A dwarf tells only the truth if he wears a blue hat; on the other hand, he only lies if he wears a red hat (a dwarf can turn his hat inside out; this situation will be called *a turning*). One day, each dwar... | [
"Ответ. 998 выворачиваний.\n\nНазовём гнома красным или синим, если на нём надет колпак соответствующего цвета. Заметим, что один гном может сказать требуемую фразу другому тогда и только тогда, когда эти гномы разноцветны: синий гном при этом скажет правду, а красный — солжёт. Теперь, если какие-то три гнома не вы... | Russia | Final round | [
"Discrete Mathematics > Combinatorics > Pigeonhole principle",
"Discrete Mathematics > Combinatorics > Coloring schemes, extremal arguments"
] | English; Russian | proof and answer | 998 | |
0kk3 | Problem:
Let $P$ be the set of points
$$
\{(x, y) \mid 0 \leq x, y \leq 25, x, y \in \mathbb{Z}\}
$$
and let $T$ be the set of triangles formed by picking three distinct points in $P$ (rotations, reflections, and translations count as distinct triangles). Compute the number of triangles in $T$ that have area larger tha... | [
"Solution:\nLemma: The area of any triangle inscribed in an $a$ by $b$ rectangle is at most $\\frac{a b}{2}$. (Any triangle's area can be increased by moving one of its sides to a side of the rectangle). Given this, because any triangle in $T$ is inscribed in a $25 \\times 25$ square, we know that the largest possi... | United States | HMMT Spring 2021 Guts Round | [
"Geometry > Plane Geometry > Analytic / Coordinate Methods > Cartesian coordinates",
"Geometry > Plane Geometry > Geometric Inequalities > Optimization in geometry",
"Number Theory > Number-Theoretic Functions > τ (number of divisors)",
"Discrete Mathematics > Combinatorics > Counting two ways"
] | null | final answer only | 436 | |
086r | Problem:
All'interno di un cerchio di raggio $1$ si tracciano $3$ archi di circonferenza, anch'essi di raggio $1$, centrando nei vertici di un triangolo equilatero inscritto nella circonferenza. Quanto vale l'area della zona ombreggiata?
(A) $\frac{\sqrt{3}}{4} \pi$
(B) $\pi-\frac{3 \sqrt{3}}{4}$
(C) $\pi-\frac{3 \sq... | [
"Solution:\n\nLa risposta è (D). Gli archi tracciati all'interno del cerchio hanno lo stesso raggio del cerchio stesso. Di conseguenza, per equiscomposizione del cerchio, l'area della parte ombreggiata in figura 1 è uguale a quella della parte ombreggiata in figura 2, ovvero è pari all'area dell'esagono inscritto i... | Italy | Progetto Olimpiadi di Matematica GARA di SECONDO LIVELLO | [
"Geometry > Plane Geometry > Miscellaneous > Constructions and loci",
"Geometry > Plane Geometry > Triangles > Triangle trigonometry",
"Geometry > Plane Geometry > Analytic / Coordinate Methods > Trigonometry"
] | null | MCQ | D | |
0gh0 | 證明只有有限多組正整數 $(a, b, c, n)$ 能使等式
$$
n! = a^{n-1} + b^{n-1} + c^{n-1}
$$ | [
"For fixed $n$ there are clearly finitely many solutions; we will show that there is no solution with $n > 100$. So assume $n > 100$. By AM-GM inequality,\n$$\n\\begin{aligned}\nn! &= 2n(n-1)(n-2)(n-3) \\cdot (3 \\cdot 4 \\cdots (n-4)) \\\\\n&\\le 2(n-1)^4 \\left( \\frac{3 + \\cdots + (n-4)}{n-6} \\right)^{n-6} = 2... | Taiwan | 2022 數學奧林匹亞競賽第一階段選訓營, 獨立研究 (二) | [
"Number Theory > Diophantine Equations > Techniques: modulo, size analysis, order analysis, inequalities",
"Algebra > Equations and Inequalities > QM-AM-GM-HM / Power Mean",
"Number Theory > Divisibility / Factorization > Prime numbers"
] | Chinese; English | proof only | null | |
09ry | Problem:
In driehoek $ABC$ is $I$ het middelpunt van de ingeschreven cirkel. Een cirkel raakt aan $AI$ in $I$ en gaat verder door $B$. Deze cirkel snijdt $AB$ nogmaals in $P$ en $BC$ nogmaals in $Q$. De lijn $QI$ snijdt $AC$ in $R$. Bewijs dat $|AR| \cdot |BQ| = |PI|^{2}$. | [
"Solution:\n\nEr is maar één configuratie. Er geldt\n$$\n\\begin{array}{rlr}\n\\angle AIP & = \\angle IBP & \\text{ (raaklijn-omtrekshoekstelling) } \\\\\n& = \\angle IBQ & (IB \\text{ is bissectrice) } \\\\\n& = \\angle IPQ & \\text{ (koordenvierhoek } PBQI \\text{ ) }\n\\end{array}\n$$\ndus vanwege Z-hoeken geldt... | Netherlands | Selectietoets | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Quadrilaterals > Cyclic quadrilaterals",
"Geometry > Plane Geometry > Circles > Tangents",
"Geometry > Plane Geometry > Miscellaneous > Angle c... | null | proof only | null | |
0f4r | Problem:
Given a real sequence $a_1, a_2, \ldots, a_n$, show that it is always possible to choose a subsequence such that
(1) for each $i \leq n - 2$ at least one and at most two of $a_i, a_{i+1}, a_{i+2}$ are chosen, and
(2) the sum of the absolute values of the numbers in the subsequence is at least $\frac{1}{6} \s... | [] | Soviet Union | 16th ASU | [
"Discrete Mathematics > Combinatorics > Pigeonhole principle",
"Discrete Mathematics > Combinatorics > Coloring schemes, extremal arguments"
] | null | proof only | null | |
0e46 | For non-zero real numbers $a$, $b$ and $c$ we have
$$
a = b + 2c, \quad a + c = b + d, \quad b = d + c.
$$
Which of the following equalities is certainly true?
(A) $d = 2c$
(B) $a = 3c$
(C) $a = 6c$
(D) $a = b + 2d$
(E) $b = 2a + 2d$ | [
"Since $b = a - 2c$ and $d = b - c = a - 3c$, we have $a + c = a - 2c + a - 3c$ and $a = 6c$."
] | Slovenia | National Math Olympiad | [
"Algebra > Prealgebra / Basic Algebra > Simple Equations"
] | null | MCQ | C | |
0ddc | Let $ABC$ be a triangle with circumcenter $O$ and incenter $I$, ex-center in angle $A$ is $J$. Denote $D$ as the tangent point of $l_a(I)$ on $BC$ and the angle bisector of angle $A$ cuts $BC$, $(O)$ respectively at $E$, $F$. The circle $(DEF)$ meets $(O)$ again at $T$. Prove that $AT$ passes through an intersection of... | [] | Saudi Arabia | Saudi Arabian Mathematical Competitions | [
"Geometry > Plane Geometry > Triangles > Triangle centers: centroid, incenter, circumcenter, orthocenter, Euler line, nine-point circle",
"Geometry > Plane Geometry > Circles > Tangents",
"Geometry > Plane Geometry > Transformations > Inversion",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing"
] | null | proof only | null | |
09xm | Let $p > 10$ be a prime number. Show that there exist positive integers $m$ and $n$ with $m + n < p$ for which $p$ is a divisor of $5^m 7^n - 1$. | [
"By Fermat's Little Theorem, we have $a^{p-1} \\equiv 1 \\mod p$ for all $a$ such that $p \\nmid a$. As $p > 10$, $p$ is odd, so $p-1$ is even. We have\n$$\n(a^{\\frac{p-1}{2}} - 1)(a^{\\frac{p-1}{2}} + 1) = a^{p-1} - 1 \\equiv 0 \\mod p.\n$$\nSo $p \\mid (a^{\\frac{p-1}{2}} - 1)(a^{\\frac{p-1}{2}} + 1)$, so $p$ is... | Netherlands | IMO Team Selection Test 3 | [
"Number Theory > Modular Arithmetic > Fermat / Euler / Wilson theorems",
"Number Theory > Residues and Primitive Roots > Quadratic residues",
"Number Theory > Residues and Primitive Roots > Primitive roots mod p / p^n",
"Number Theory > Residues and Primitive Roots > Multiplicative order"
] | English | proof only | null | |
08z1 | Find the smallest four-digit integer divisible by three and greater than $2022$ such that there are exactly two types of numbers that appear in the digits. | [
"We call four-digit integers **good** if their digits consist of exactly two types of numbers.\nFirst, the upper two digits of integers in $[2000, 2099]$ are $20$. So the only good integers in the range are $2000$, $2002$, $2020$, and $2022$. But all of them are less than or equal to $2022$.\nSecond, the upper two ... | Japan | Japan 2022 | [
"Number Theory > Divisibility / Factorization",
"Algebra > Prealgebra / Basic Algebra > Integers"
] | null | proof and answer | 2112 | |
07g6 | Let $ABCD$ be a rhombus and let $\omega$ be its incircle. Let $M$ be the midpoint of $AB$ and $K$ be a point inside $ABCD$ such that $MK$ is tangent to $\omega$. Prove that $CDKM$ is cyclic. | [
"Let $L$ be the intersection of $KM$ and $CD$. The quadrilateral $MLCB$ has an incircle centered at $O$. So $OL$ and $OM$ are angle-bisectors of $\\angle MLC$ and $\\angle BML$, respectively. Further, $BM \\parallel CL$, these two arguments yielding $\\angle LOM = 90^\\circ$. Therefore $LO$ is tangent to the circum... | Iran | 38th Iranian Mathematical Olympiad | [
"Geometry > Plane Geometry > Quadrilaterals > Cyclic quadrilaterals",
"Geometry > Plane Geometry > Quadrilaterals > Inscribed/circumscribed quadrilaterals",
"Geometry > Plane Geometry > Circles > Tangents",
"Geometry > Plane Geometry > Miscellaneous > Angle chasing"
] | null | proof only | null | |
08yq | Let $P$ be a point inside isosceles triangle $ABC$ with $AB = AC$, and let $D, E, F$ be the feet of the perpendicular from $P$ to $BC, CA, AB$, respectively. If $BD = 9$, $CD = 5$, $PE = 2$, $PF = 5$, find $AB$.
 | [
"$4\\sqrt{7}$\nLet $M$ be the midpoint of segment $BC$, and let $Q$ (resp. $R$) be the intersection of the line through $P$ parallel to segment $BC$ with segments $AB$ (resp. $AC$). As $AB = AC$, we have $\\angle ABM = \\angle AQP = \\angle ARP$, which yields that the right-angled triangles $AMB$, $PFQ$, $PER$ are ... | Japan | Japan Mathematical Olympiad | [
"Geometry > Plane Geometry > Miscellaneous > Angle chasing",
"Geometry > Plane Geometry > Miscellaneous > Distance chasing"
] | English | proof and answer | 4*sqrt(7) | |
0idc | Let $\mathbb{N}_0^+$ and $\mathbb{Q}$ be the set of nonnegative integers and rational numbers, respectively. Define the function $f : \mathbb{N}_0^+ \to \mathbb{Q}$ by $f(0) = 0$ and
$$f(3n + k) = -\frac{3f(n)}{2} + k, \quad \text{for } k = 0, 1, 2.$$
Prove that $f$ is one-to-one, and determine its range. | [
"We prove that the range of $f$ is the set $T$ of rational numbers of the form $m/2^n$ for $m \\in \\mathbb{Z}$ and $n \\in \\mathbb{N}_0^+$ (also known as the *dyadic rational numbers*). For $x, y \\in T$, we write $x \\equiv y \\pmod 3$ to mean that the numerator of $x - y$, when written in lowest terms, is divis... | United States | USA IMO | [
"Algebra > Algebraic Expressions > Functional Equations > Injectivity / surjectivity"
] | null | proof and answer | Range(f) = { m/2^n : m ∈ ℤ, n ∈ ℕ_0^+ } (the dyadic rationals). Also, f is injective. | |
07bp | Let $n$ be a natural number. Determine the smallest natural number $k$ such that among any $k$ natural numbers, it is always possible to select an even number of them having a sum divisible by $n$. | [
"We start with a lemma.\n\n**Lemma 1.** Let $a_1, a_2, \\dots, a_n$ be $n$ even integers. Then there is a subsequence $i_1 < i_2 < \\dots < i_k$ of $1, 2, \\dots, n$ such that $a_{i_1} + \\dots + a_{i_k}$ is divisible by $2n$.\n\n*Proof.* Consider the following integers\n$$\nS_i = \\frac{1}{2}(a_1 + a_2 + \\dots + ... | Iran | Iranian Mathematical Olympiad | [
"Number Theory > Modular Arithmetic",
"Discrete Mathematics > Combinatorics > Pigeonhole principle"
] | null | proof and answer | If n is odd, k = 2n. If n is even, k = n + 1. |
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