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1.3. A ballpoint pen costs 10 rubles, a fountain pen costs 60 rubles, and a gel pen costs 70 rubles. What is the maximum number of fountain pens that can be bought if you need to buy exactly 25 pens in total and among them there must be pens of all three types, and you need to spend exactly 1000 rubles on them?
Answer: 9. Comments. The solutions are two triples of integers $(11,9,5)$ and $(12,3,10)$.
9
Algebra
math-word-problem
Yes
Yes
olympiads
false
1.4. A ballpoint pen costs 10 rubles, a gel pen costs 30 rubles, and a fountain pen costs 60 rubles. What is the maximum number of ballpoint pens that can be bought if you need to buy exactly 20 pens in total and among them there must be pens of all three types, and you need to spend exactly 500 rubles on them?
Answer: 11. Comments. The solutions are two triples of integers $(11,5,4)$ and $(8,10,2)$.
11
Algebra
math-word-problem
Yes
Yes
olympiads
false
3.1. A plane parallel to the base of a quadrilateral pyramid with a volume of 81 cuts off a smaller pyramid with a volume of 3. Find the volume of the pyramid whose four vertices coincide with the vertices of the section, and the fifth vertex lies in the base plane of the larger pyramid.
Answer: 6. Solution. If we denote the first given volume as $V$, and the second as $v$ (in this case $V=81, v=3$), then the larger pyramid and the smaller pyramid are similar with a similarity coefficient of $\sqrt[3]{\frac{V}{v}}$. Therefore, the height $H$ of the larger pyramid relates to the height $h$ of the smalle...
6
Geometry
math-word-problem
Yes
Yes
olympiads
false
7.1. Find the number of all integer solutions of the inequality $\sqrt{1-\sin \frac{\pi x}{4}-3 \cos \frac{\pi x}{2}}-\sqrt{6} \cdot \sin \frac{\pi x}{4} \geq 0$, belonging to the interval [1991; 2013].
Answer: 8. Solution. Denoting $\sin \frac{\pi x}{4}=t$, we get $\sqrt{1-t-3\left(1-2 t^{2}\right)} \geq \sqrt{6} \cdot t$, or $\sqrt{6 t^{2}-t-2} \geq \sqrt{6} \cdot t$. For non-negative $t$, we obtain $6 t^{2}-t-2 \geq 6 t^{2}$, or $t \leq-2$, which means there are no solutions. For $t<0$, the condition $6 t^{2}-t-2 \...
8
Inequalities
math-word-problem
Yes
Yes
olympiads
false
7.2. Find the number of all integer solutions of the inequality $\sqrt{3 \cos \frac{\pi x}{2}-\cos \frac{\pi x}{4}+1}-\sqrt{6} \cdot \cos \frac{\pi x}{4} \geq 0$, belonging to the interval [1991; 2013].
Answer: 9. Comments. Solution of the inequality: $\frac{8}{3}+8 k \leq x \leq \frac{16}{3}+8 k$. From the given interval, the following numbers will be included in the answer: 1995, 1996, 1997, 2003, 2004, 2005, 2011, 2012, 2013 - 9 numbers.
9
Inequalities
math-word-problem
Yes
Yes
olympiads
false
7.3. Find the number of all integer solutions of the inequality $\sqrt{1+\sin \frac{\pi x}{4}-3 \cos \frac{\pi x}{2}}+\sqrt{6} \cdot \sin \frac{\pi x}{4} \geq 0$, belonging to the interval [1991; 2013].
Answer: 9. Comments. Solution of the inequality: $\frac{2}{3}+8 k \leq x \leq \frac{10}{3}+8 k$. From the given interval, the following numbers will be included in the answer: 1993, 1994, 1995, 2001, 2002, 2003, 2009, 2010, 2011 - 9 numbers.
9
Inequalities
math-word-problem
Yes
Yes
olympiads
false
7.4. Find the number of all integer solutions of the inequality $\sqrt{3 \cos \frac{\pi x}{2}+\cos \frac{\pi x}{4}+1}+\sqrt{6} \cdot \cos \frac{\pi x}{4} \geq 0$, belonging to the interval $[1991 ; 2013]$.
Answer: 9. Comments. Solution of the inequality: $-\frac{4}{3}+8 k \leq x \leq \frac{4}{3}+8 k$. From the given interval, the following will be included in the answer: 1991, 1992, 1993, 1999, 2000, 2001, 2007, 2008, 2009 - 9 numbers.
9
Inequalities
math-word-problem
Yes
Yes
olympiads
false
3.1. From one point on a circular track, a pedestrian and a cyclist started simultaneously in the same direction. The cyclist's speed is $55\%$ greater than the pedestrian's speed, and therefore the cyclist overtakes the pedestrian from time to time. At how many different points on the track will the overtakes occur?
Answer: 11. Solution: Let's assume the length of the path is 55 (in some units), and the speeds of the pedestrian and the cyclist are $100 x$ and $155 x$. Then, the overtakes will occur every $1 / x$ units of time. During this time, the pedestrian covers 100 units, which means he will be 10 units away in the opposite ...
11
Combinatorics
math-word-problem
Yes
Yes
olympiads
false
7.1. Solve the equation $\frac{n!}{2}=k!+l!$ in natural numbers, where $n!=1 \cdot 2 \cdot \ldots n$. If there are no solutions, write 0; if there is one solution, write $n$; if there are multiple solutions, write the sum of the values of $n$ for all solutions. Recall that a solution is a triplet $(n, k, l)$; if soluti...
Answer: 10 (all triples of solutions $(n, k, l):(3,1,2),(3,2,1),(4,3,3)$). Solution. Note that if $k4$, then $n!>4 \cdot(n-1)!\geqslant 2 \cdot(k!+l!)$, so there are no such solutions. If $n=2$, we get $1=k!+l!$ - no solutions; if $n=3$, the equation $3=k!+l!$ has two solutions: $k=1, l=2$ and $k=2, l=1$; if $n=4$, th...
10
Number Theory
math-word-problem
Yes
Yes
olympiads
false
1. Given a parallelogram $A B C D$ and points $A_{1}, B_{1}, C_{1}$, and $D_{1}$ are chosen such that point $A$ is the midpoint of segment $D D_{1}$, point $B$ is the midpoint of $A A_{1}$, point $C$ is the midpoint of $B B_{1}$, and point $D$ is the midpoint of $C C_{1}$. Find the area of $A_{1} B_{1} C_{1} D_{1}$, gi...
# Answer: 5 ## Solution: ![](https://cdn.mathpix.com/cropped/2024_05_06_bdfe3271f0fede0d79bbg-1.jpg?height=1016&width=1034&top_left_y=977&top_left_x=274) Notice that triangles $\triangle A B C$ and $\triangle A B D_{1}$ are congruent, hence their areas are equal. Triangles $\triangle A B D_{1}$ and $\triangle A_{1} ...
5
Geometry
math-word-problem
Yes
Yes
olympiads
false
4. Kolya started playing $W o W$ at the moment when the hour and minute hands were opposite. He finished playing after an integer number of minutes, and at the end, the minute hand coincided with the hour hand. How long did he play (if it is known that he played for less than 12 hours)
Solution: The minute hand catches up with the hour hand at a speed of $\frac{11^{\circ}}{2}$ /min. For them to coincide, the difference in their angles of rotation should be $180+360 k$. This value is a multiple of 11 when $k=5,16, \ldots$. According to the problem, only $k=5$ fits, which gives us 6 o'clock.
6
Logic and Puzzles
math-word-problem
Yes
Yes
olympiads
false
2. A stack of A4 sheets was folded in half and folded in two (resulting in an A5 booklet). After that, the pages of the resulting booklet were renumbered: $1,2,3, \ldots$ It turned out that the sum of the numbers on one of the sheets was 74. How many sheets were in the stack?
Answer: 9. Solution. Note that the sum of the numbers on each leaf is the same. If the last page has the number $n$, then on the first leaf, the numbers will be $1,2, n-1$ and $n$. Therefore, $2n + 2 = 74$, from which we get that the number of pages $n=36$. Four pages are placed on each leaf, so there were 9 leaves.
9
Number Theory
math-word-problem
Yes
Yes
olympiads
false
5. In a $3 \times 3$ table, the following numbers are written: | 10 | 20 | 40 | | :---: | :---: | :---: | | 32 | 61 | 91 | | 100 | 1000 | 2000 | It is allowed to swap any two numbers in one move. What is the minimum number of moves required to achieve that the sum of the numbers in each column is divisible by $3 ?$
Answer: 2. Solution. | 1 | 2 | 1 | | :--- | :--- | :--- | | 2 | 1 | 1 | | 1 | 1 | 2 | Let's write down the remainders of these numbers when divided by 3. It is not hard to notice that the sum of the numbers is divisible by 3 if and only if the sum of the corresponding remainders is divisible by 3. The remainders equa...
2
Number Theory
math-word-problem
Yes
Yes
olympiads
false
6. Find the number of integers from 1 to 3400 that are divisible by 34 and have exactly 2 odd natural divisors. For example, the number 34 has divisors $1,2,17$ and 34, exactly two of which are odd.
Answer: 7. Solution. It is obvious that if a number is divisible by 34, then its divisors will always be 1 and 17. According to the condition, there should be no other odd divisors, so these must be numbers of the form $17 \cdot 2^{k}$, $k \geqslant 1$ (and only they). These numbers fall within the specified range for ...
7
Number Theory
math-word-problem
Yes
Yes
olympiads
false
2.1. Find all values of $a$ for which the quadratic function $f(x)=a x^{2}-2 a x+1$ takes values, the modulus of which does not exceed 2, at all points of the interval $[0 ; 2]$. In your answer, specify the total length of the intervals to which the found values of $a$ belong.
Answer: 4 (the desired set of values for $a:[-1 ; 0) \cup(0 ; 3]$). Solution. For the function $f(x)$ to be quadratic, it is necessary that $a \neq 0$. The vertex of the parabola, which is the graph of the given function, is located at the point $(1 ; 1-a)$. Since $f(0)=f(2)=1$, the condition of the problem is satisfi...
4
Algebra
math-word-problem
Yes
Yes
olympiads
false
2.3. Find all values of $a$ for which the quadratic function $f(x)=a x^{2}+2 a x-1$ takes values, the modulus of which does not exceed 3, at all points of the interval $[-2 ; 0]$. In your answer, specify the total length of the intervals to which the found values of $a$ belong.
Answer: 6 (the set of desired values of $a$: $[-4 ; 0) \cup(0 ; 2]$).
6
Algebra
math-word-problem
Yes
Yes
olympiads
false
2.4. Find all values of $a$ for which the quadratic function $f(x)=a x^{2}+4 a x-1$ takes values, the modulus of which does not exceed 4, at all points of the interval $[-4 ; 0]$. In your answer, specify the total length of the intervals to which the found values of $a$ belong.
Answer. 2 (the set of desired values of $a: \left[-\frac{5}{4} ; 0\right) \cup\left(0 ; \frac{3}{4}\right]$).
2
Algebra
math-word-problem
Yes
Yes
olympiads
false
6.1. Solve the equation $\frac{n!}{2}=k!+l!$ in natural numbers, where $n!=1 \cdot 2 \ldots n$. If there are no solutions, indicate 0; if there is one solution, indicate $n$; if there are multiple solutions, indicate the sum of the values of $n$ for all solutions. Recall that a solution is a triplet ( $n, k, l$); if so...
Answer: 10 (all triples of solutions $(n, k, l):(3,1,2),(3,2,1),(4,3,3)$). Solution. Note that if $k4$, then $n!>4 \cdot(n-1)!\geqslant 2 \cdot(k!+l!)$, so there are no such solutions. If $n=2$, we get $1=k!+l!$ - no solutions; if $n=3$, the equation $3=k!+l!$ has two solutions: $k=1, l=2$ and $k=2, l=1$; if $n=4$, th...
10
Number Theory
math-word-problem
Yes
Yes
olympiads
false
7.1. In an acute-angled triangle $A B C$, the median $B M$ and the altitude $C H$ were drawn. It turned out that $B M=C H=\sqrt{3}$, and $\angle M B C=\angle A C H$. Find the perimeter of triangle $A B C$.
Answer: 6. Solution. We will prove that triangle $ABC$ is equilateral, with all sides equal to 2. Drop a perpendicular $MK$ from point $M$ to side $AB$. In triangle $BMK$, the leg $KM$ is half the hypotenuse $MB$, so $\angle KBM = 30^{\circ}$. Let $O$ be the intersection of $MB$ and $CH$, then $\angle MOC = 60^{\circ}...
6
Geometry
math-word-problem
Yes
Yes
olympiads
false
Problem 4. For an infinite sequence of numbers $x_{1}, x_{2}, x_{3}, \ldots$, for all natural $n \geq 4$, the relation $x_{n}=x_{n-1} \cdot x_{n-3}$ holds. It is known that $x_{1}=1, x_{2}=1, x_{3}=-1$. Find $x_{2022}$.
# Answer: 1. Solution. All members of the sequence have a modulus of 1. Mark the positive ones with a plus and the negative ones with a minus. Write out the beginning of the sequence: $$ [++---+-]++---+-++\ldots $$ It is clear that three consecutive members completely determine how the sequence will look further. Th...
1
Algebra
math-word-problem
Yes
Yes
olympiads
false
Problem 6. In a square room, there is a light bulb on each wall that can shine in one of the seven colors of the rainbow. There are no light bulbs in the room that shine the same color. In one move, a person can change the color of one of the light bulbs to a color that is not used by any light bulb in the room at the ...
Answer: 8 moves. Solution. Each light bulb on the walls of the room must change color 6 times, and there are four walls, so the total number of color changes is at least 24. On the other hand, in one move, the color of three light bulbs changes, so the number of moves is at least 8. An example for 8 moves can be provi...
8
Combinatorics
math-word-problem
Yes
Yes
olympiads
false
1. Detective Podberezyakov is pursuing Maksim Detochkin (each driving their own car). At the beginning, both were driving on the highway at a speed of 60 km/h, with Podberezyakov lagging behind Detochkin by 2 km. Upon entering the city, each of them reduced their speed to 40 km/h, and upon exiting the city, finding the...
Answer: 1 km. Solution: At the moment Detochkin entered the city, Podberezyakov was 2 km behind him. Podberezyakov covered this distance in 2/60 hours, during which time Detochkin traveled $\frac{2}{60} \cdot 40$ km. That is, the distance was multiplied by 40/60. Similarly, when exiting the city and transitioning to t...
1
Logic and Puzzles
math-word-problem
Yes
Yes
olympiads
false
3. And our cat gave birth to kittens yesterday! It is known that the two lightest kittens weigh a total of 80 g, the four heaviest weigh 200 g, and the total weight of all the kittens is 500 g. How many kittens did the cat give birth to?
Answer: 11. Solution: The two lightest weigh 80 g, so the others weigh no less than 40 g each. Similarly, we find that all except the 4 heaviest weigh no more than 50 g. Consider the kittens that are not among the 2 lightest and the 4 heaviest. Their total weight is 500-200-80=220g. There must be 5 of them, because if...
11
Logic and Puzzles
math-word-problem
Yes
Yes
olympiads
false
3. Find the sum $$ \begin{aligned} & \frac{1}{(\sqrt[4]{1}+\sqrt[4]{2})(\sqrt{1}+\sqrt{2})}+\frac{1}{(\sqrt[4]{2}+\sqrt[4]{3})(\sqrt{2}+\sqrt{3})}+ \\ & +\ldots+\frac{1}{(\sqrt[4]{9999}+\sqrt[4]{10000})(\sqrt{9999}+\sqrt{10000})} \end{aligned} $$
Answer: 9. Solution. If we multiply the numerator and denominator of the fraction $\frac{1}{(\sqrt{n}+\sqrt{n}+1)(\sqrt{n}+\sqrt{n+1})}$ by $\sqrt[4]{n}-\sqrt[4]{n+1}$, we get $\sqrt[4]{n+1}-\sqrt[4]{n}$. The specified ![](https://cdn.mathpix.com/cropped/2024_05_06_94cb46a707e666e84118g-2.jpg?height=68&width=1586&top_...
9
Algebra
math-word-problem
Yes
Yes
olympiads
false
6. Given a parallelogram $A B C D$ and points $A_{1}, B_{1}, C_{1}$, and $D_{1}$ are chosen such that point $A$ is the midpoint of segment $D D_{1}$, point $B$ is the midpoint of $A A_{1}$, point $C$ is the midpoint of $B B_{1}$, and point $D$ is the midpoint of $C C_{1}$. a) Prove that $A_{1} B_{1} C_{1} D_{1}$ is als...
# Answer: b) 5 ## Solution: ![](https://cdn.mathpix.com/cropped/2024_05_06_c8e9c92d7b49aca92e31g-2.jpg?height=1014&width=1016&top_left_y=1189&top_left_x=286) a) From the properties of a parallelogram, it follows that $A B = C D, \angle B A D_{1} = 180^{\circ} - \angle B A D = 180^{\circ} - \angle B C D = \angle D C ...
5
Geometry
proof
Yes
Yes
olympiads
false
1. The sum of positive integers is 11. In the first part of this equation, identical numbers are hidden behind cards with the same letters, and different numbers - behind cards with different letters. Consider the equation: $\quad \mathbf{C}+\mathbf{y}+\mathbf{M}+\mathbf{M}+\mathbf{A}=11$. Can you tell which number i...
Answer: 1. Solution. If $M=1$, then the sum $C+y+A=9$, which is only possible with the set of numbers 2, 3, 4 (in any order). If $M=2$, then the sum $C+y+A=7$, which is impossible, as this sum is not less than $1+3+4=8$. If $M>2$, this is even more impossible.
1
Logic and Puzzles
math-word-problem
Yes
Yes
olympiads
false
3. Having walked $2 / 5$ of the length of a narrow bridge, a pedestrian noticed that a car was approaching the bridge from behind. Then he walked back and met the car at the beginning of the bridge. If the pedestrian had continued walking forward, the car would have caught up with him at the end of the bridge. Find the...
Answer: 5. Solution. In the time $t$ that the pedestrian walked towards the car until they met at the beginning of the bridge, he covered $2 / 5$ of the bridge's length. Therefore, if the pedestrian continued walking forward, in time $t$ he would have covered another $2 / 5$ of the bridge's length, and he would have $...
5
Algebra
math-word-problem
Yes
Yes
olympiads
false
6. How many solutions does the equation $$ \frac{1}{(x-1)^{2}}+\frac{1}{(x-2)^{2}}=\frac{2}{x^{2}} ? $$
Answer: 1. Solution. Let us consider the functions $$ f(x)=\frac{1}{(x-1)^{2}}+\frac{1}{(x-2)^{2}} \quad \text { and } \quad g(x)=\frac{2}{x^{2}}. $$ ![](https://cdn.mathpix.com/cropped/2024_05_06_2cf4ae7b738ff8febec4g-2.jpg?height=443&width=653&top_left_y=721&top_left_x=1318) For $x < 0$, both functions $f$ and $g...
1
Algebra
math-word-problem
Yes
Yes
olympiads
false
7. Given three points, the distances between which are 4, 6, and 7. How many pairwise distinct triangles exist for which each of these points is either a vertex or the midpoint of a side?
Answer: 11. Solution. Let's list all the constructions of triangles that satisfy the condition of the problem, indicating the lengths of the sides. | | Description of the Triangle | | Lengths of Sides | | :---: | :---: | :---: | :---: | | â„–1 | All points are vertices | | $4,6,7$ | | | One point is a vertex, two a...
11
Geometry
math-word-problem
Yes
Yes
olympiads
false
8. In a commercial football tournament, five teams participated. Each was supposed to play exactly one match against each other. Due to financial difficulties, the organizers canceled some games. In the end, it turned out that all teams had scored a different number of points, and no team had a zero in the points score...
Answer: 6. Solution. The minimum possible total score: $1+2+3+4+5=15$. In one game, a maximum of 3 points (in total) can be scored. Therefore, there were at least 5 games. However, if there were exactly 5 games, then all games would have to end with one of the teams winning, and then no team would have scored exactly ...
6
Combinatorics
math-word-problem
Yes
Yes
olympiads
false
Problem 4. How many triples of numbers $a, b, c$ exist, each of which is a root of the corresponding equation $a x^{2}+b x+c=0$?
Answer: 5. Solution. If $a=0$ or $a=b=c$, then $a=b=c=0$. Otherwise: if $a=b \neq c$, then either $a=b=-1, c=0$, or $a=b=1, c=-2$; if $a \neq b=c$, then either $a=1, b=c=-0.5$; if $a=c \neq b$, then $a=c=c_{0}, b=1 / c_{0}$, where the number $c_{0}<0$ is the unique root of the equation $c^{3}+c=-1$.
5
Algebra
math-word-problem
Yes
Yes
olympiads
false
Task 1. Every time my brother tells the truth, our grandmother sneezes. One day, my brother said he got a "5" in math, but grandmother didn't sneeze. Then, slightly doubting his first words, he said he got a "4," and grandmother sneezed. Encouraged by grandmother's sneeze, he confirmed that he definitely got no less th...
Answer: $« 2 »$. Solution. If the grandmother did not sneeze, then the brother definitely lied, so he did not get a "5" and even more than that, less than 3. If the grandmother did sneeze, then it is not certain that he told the truth at that moment, as the condition does not prohibit the grandmother from sneezing whe...
2
Logic and Puzzles
math-word-problem
Yes
Yes
olympiads
false
1.1. (2 points) In a nine-story building, there are 4 apartments on each floor. How many entrances are there in this building if there are a total of 180 apartments?
Answer: 5. Solution. The number of entrances is $180:(4 \cdot 9)=5$.
5
Logic and Puzzles
math-word-problem
Yes
Yes
olympiads
false
5.1. (14 points) The old man was pulling the turnip, and one by one, the old woman, the granddaughter, the dog, and the cat joined him. They pulled and pulled, but couldn't pull out the turnip! The cat called the mouse. They pulled and pulled, and finally pulled out the turnip! It is known that each subsequent particip...
Answer: 2. Solution. The old woman, the granddaughter, Zhuchka, and the mouse pull with a combined force of $$ \frac{3}{4}+\left(\frac{3}{4}\right)^{2}+\left(\frac{3}{4}\right)^{3}+\left(\frac{3}{4}\right)^{5}=\frac{2019}{1024}=1 \frac{995}{1024} $$ of the force of the old man. Therefore, two men need to be called.
2
Algebra
math-word-problem
Yes
Yes
olympiads
false
7.1. (14 points) Misha drew a triangle with a perimeter of 11 and cut it into parts with three straight cuts parallel to the sides, as shown in the figure. The perimeters of the three shaded figures (trapezoids) turned out to be 5, 7, and 9. Find the perimeter of the small triangle that resulted from the cutting. #
# Answer: 10. ![](https://cdn.mathpix.com/cropped/2024_05_06_38daf1cc3b5132f798e9g-3.jpg?height=325&width=434&top_left_y=89&top_left_x=1485) Solution. Since opposite sides of parallelograms are equal, the lateral sides of each resulting trapezoid are equal to the corresponding segments on the sides of the original tr...
10
Geometry
math-word-problem
Yes
Yes
olympiads
false
8.1. (14 points) Two people spend time playing a game: they take turns naming prime numbers not exceeding 100 such that the last digit of the number named by one player is equal to the first digit of the number named by the next player (except for the first prime number named in the game). Repeating numbers that have a...
# Answer: 3. Solution. We will describe a winning strategy for the first player. First, the first player names a prime number ending in 9 and different from 79 (for example, 19). Since among the numbers $90, \ldots, 99$ the only prime is 97, the second player must name this number on their next move. Then, on the thir...
3
Number Theory
proof
Yes
Yes
olympiads
false
# Task 1. Mom told Dima that he should eat 13 spoons of porridge. Dima told his friend that he had eaten 26 spoons of porridge. Each child, telling about Dima's feat, increased the amount of porridge Dima had eaten by 2 or 3 times. As a result, one of the children told Dima's mom about 33696 spoons of porridge. How ma...
Answer: 9 Solution. $33696=2^{5} \cdot 3^{4} \cdot 13$. From this, it follows that the story of the feat was retold 5 times with the amount of porridge doubling and 4 times with it tripling, totaling 9 times. ## B-2 Dad persuaded Natasha to eat 11 spoons of porridge. Natasha told her friend that she had eaten 22 spo...
9
Logic and Puzzles
math-word-problem
Yes
Yes
olympiads
false
5. On graph paper (the side of a cell is 1 cm) a rectangle is drawn, the sides of which lie on the grid lines, with one side being 7 cm shorter than the other. It turned out that it can be cut into several pieces along the grid lines and form a square from them. What can the side of this square be? Find all possible va...
Answer: 6 cm. Solution. Let the larger side of the rectangle be $k$ cm, where $k>7$, and the side of the resulting square be $n$ cm. Then, from the equality of the areas, we get $k(k-7)=n^{2}$. Since $n<k$, let $n=k-m$, where $m \geqslant 1$. Then $k^{2}-7 k=(k-m)^{2}, k^{2}-7 k=k^{2}-2 m k+m^{2}$, from which $m(2 k-m...
12
Geometry
math-word-problem
Yes
Yes
olympiads
false
4. On a vast meadow, a lamb is grazing, tied with two ropes to two stakes (each stake with its own rope). a) What shape will the area on the meadow be, where the lamb can eat the grass? b) In the middle between the stakes, a rose grows, and the distance between the stakes is 20 meters. What should the lengths of the ...
Answer: b) Exactly one of the ropes is shorter than 10 m. Solution. a) The desired figure is the intersection of two circles with centers at the stakes and radii equal to the lengths $l_{1}$ and $l_{2}$ of the first and second ropes, respectively. Therefore, it can be either the figure shaded in Fig. 3, or a complete ...
1
Geometry
math-word-problem
Yes
Yes
olympiads
false
3. Find the number of numbers from 1 to 3400 that are divisible by 34 and have exactly 2 odd natural divisors. For example, the number 34 has divisors $1,2,17$ and 34, exactly two of which are odd.
Answer: 7. Solution. It is obvious that if a number is divisible by 34, then its divisors will always include 1 and 17. According to the condition, there should be no other odd divisors, so these must be numbers of the form $17 \cdot 2^{k}$, $k \geqslant 1$ (and only they). These numbers fall within the specified range...
7
Number Theory
math-word-problem
Yes
Yes
olympiads
false
6. Find the sum $$ \begin{aligned} & \frac{1}{(\sqrt[4]{1}+\sqrt[4]{2})(\sqrt{1}+\sqrt{2})}+\frac{1}{(\sqrt[4]{2}+\sqrt[4]{3})(\sqrt{2}+\sqrt{3})}+ \\ & +\ldots+\frac{1}{(\sqrt[4]{9999}+\sqrt[4]{10000})(\sqrt{9999}+\sqrt{10000})} \end{aligned} $$
Answer: 9. Solution. If we multiply the numerator and denominator of the fraction $\frac{1}{(\sqrt[4]{n}+\sqrt[4]{n+1})(\sqrt{n}+\sqrt{n+1})}$ by $\sqrt[4]{n}-\sqrt[4]{n+1}$, we get $\sqrt[4]{n+1}-\sqrt[4]{n}$. The specified sum transforms to $(\sqrt[4]{2}-\sqrt[4]{1})+(\sqrt[4]{3}-\sqrt[4]{2})+\ldots+(\sqrt[4]{10000}-...
9
Algebra
math-word-problem
Yes
Yes
olympiads
false
2.1. Trapezoid $A B C D$ with base $A D=6$ is inscribed in a circle. The tangent to the circle at point $A$ intersects lines $B D$ and $C D$ at points $M$ and $N$ respectively. Find $A N$, if $A B \perp M D$ and $A M=3$.
Answer: 12. Solution. The condition $A B \perp M D$ means that $\angle A B D=90^{\circ}$, that is, the base $A D$ is the diameter of the circle. Since the trapezoid is inscribed, it is isosceles. $\triangle D N A$ and $\triangle D A C$ are similar as right triangles with a common angle. From the equality of angles $\an...
12
Geometry
math-word-problem
Yes
Yes
olympiads
false
3.1. The parabola $y=x^{2}$ intersects with the line $y=25$. A circle is constructed on the segment between the intersection points of the parabola and the line as its diameter. Find the area of the convex polygon whose vertices are the intersection points of the given circle and the parabola. Provide the nearest integ...
Answer: 10. Solution. The parabola $y=x^{2}$ intersects the line $y=a$ at points with coordinates $( \pm \sqrt{a} ; a)$. Each of the intersection points of the circle and the parabola mentioned in the problem has coordinates $\left(x ; x^{2}\right)$. For such a point, the distance to the line $y=a$ is $\left|a-x^{2}\ri...
10
Geometry
math-word-problem
Yes
Yes
olympiads
false
4.1. Solve the equation $\left(x^{2}-2 x+4\right)^{x^{2}-2 x+3}=625$. In the answer, specify the sum of the squares of all its roots. If there are no roots, put 0.
Answer: 6. Solution. Since $x^{2}-2 x+3>0$, then $x^{2}-2 x+4>1$. The function $f(z)=z^{z-1}$ is increasing for $z>1$ (if $1<z_{1}<z_{2}$, then $f\left(z_{1}\right)=z_{1}^{z_{1}-1}<z_{1}^{z_{2}-1}<z_{2}^{z_{2}-1}=f\left(z_{2}\right)$. Therefore, the original equation, which is of the form $f\left(x^{2}-2 x+4\right)=f(5...
6
Algebra
math-word-problem
Yes
Yes
olympiads
false
7.1. A team of athletes, one third of whom are snowboarders, descended from the mountain. Some of them got into a cable car carriage, which can accommodate no more than 10 people, while all the others descended on their own, and their number turned out to be more than $45 \%$, but less than $50 \%$ of the total number....
Answer: 5. Solution. If there were $x$ snowboarders and $y$ people descended on the cable car, then there were a total of $3 x$ athletes and $\left\{\begin{array}{l}\frac{9}{20}=\frac{45}{100}<\frac{3 x-y}{3 x}<\frac{50}{100}=\frac{10}{20}, \\ y \leq 10\end{array} \Rightarrow\right.$ $\left\{\begin{array}{l}x<\frac{20}...
5
Number Theory
math-word-problem
Yes
Yes
olympiads
false
9.1. Find the number of roots of the equation $$ \operatorname{arctg}\left(\operatorname{tg}\left(\sqrt{13 \pi^{2}+12 \pi x-12 x^{2}}\right)\right)=\arcsin \left(\sin \sqrt{\frac{13 \pi^{2}}{4}+3 \pi x-3 x^{2}}\right) $$
Answer: 9. Solution. Let's make the substitution $t=\sqrt{\frac{13 \pi^{2}}{4}+3 \pi x-3 x^{2}}$. Since $\frac{13 \pi^{2}}{4}+3 \pi x-3 x^{2}=4 \pi^{2}-3\left(x-\frac{\pi}{2}\right)^{2}$, then $0 \leq t \leq 2 \pi$. The original equation, after the specified substitution, transforms into the equation $\operatorname{arc...
9
Algebra
math-word-problem
Yes
Yes
olympiads
false
1.1. (2 points) In a large family, one of the children has 3 brothers and 6 sisters, while another has 4 brothers and 5 sisters. How many boys are there in this family
Answer: 4. Solution. In the family, boys have fewer brothers than girls have, and girls have fewer sisters than boys have. Therefore, there are 4 boys and 6 girls in the family.
4
Logic and Puzzles
math-word-problem
Yes
Yes
olympiads
false
5.1. Let $S(n)$ be the sum of the digits in the decimal representation of the number $n$. Find $S\left(S\left(S\left(S\left(2017^{2017}\right)\right)\right)\right)$. Answer. 1.
Solution. Since $2017^{2017}<10000^{2017}$, the number of digits in the representation of $2017^{2017}$ does not exceed $4 \cdot 2017=$ 8068, and their sum $S\left(2017^{2017}\right)$ does not exceed $9 \cdot 8068=72612$. Then we sequentially obtain $S\left(S\left(2017^{2017}\right)\right) \leqslant 6+9 \cdot 4=42, S\l...
1
Number Theory
math-word-problem
Yes
Yes
olympiads
false
1. Two trains, each containing 15 identical cars, were moving towards each other at constant speeds. Exactly 28 seconds after the first cars of the trains met, passenger Sasha, sitting in the third car, passed passenger Valera from the oncoming train, and another 32 seconds later, the last cars of these trains had comp...
Solution. Since 60 seconds have passed from the moment the "zero" cars parted ways (which is also the moment the first cars met) to the moment the 15th cars parted ways, the next cars parted ways every $60: 15=4$ seconds. Therefore, after 28 seconds, the 7th cars of the trains had just parted ways, meaning the 7th car ...
12
Logic and Puzzles
math-word-problem
Yes
Yes
olympiads
false
2. Find the area of the figure defined on the coordinate plane by the system $$ \left\{\begin{array}{l} \sqrt{1-x}+2 x \geqslant 0 \\ -1-x^{2} \leqslant y \leqslant 2+\sqrt{x} \end{array}\right. $$
Answer: 4. Solution. The system is defined under the condition $x \in[0,1]$, under which the first inequality of the system is satisfied. Since the functions $y=x^{2}$ and $y=\sqrt{x}$ are inverses of each other for $x \in[0,1]$, the area of the figure defined by the conditions $x \in[0,1],-1-x^{2} \leqslant y \leqsla...
4
Inequalities
math-word-problem
Yes
Yes
olympiads
false
# Problem 3. In triangle $A B C$, the bisector $B E$ and the median $A D$ are equal and perpendicular. Find the area of triangle $A B C$, if $A B=\sqrt{13}$.
Answer: 12 Solution. Let $A B=c, B E=A D=2 a$. Since triangle $A B D$ is isosceles (the bisector is perpendicular to the base, $A B=B D=c, B C=2 c$), then by the formula for the length of the bisector (where $\angle A B C=\beta$) $2 a=\frac{4 c^{2}}{3 c} \cos \frac{\beta}{2} \Leftrightarrow \frac{3 a}{2}=c \cos \frac{...
12
Geometry
math-word-problem
Yes
Yes
olympiads
false
1. Points $A$ and $B$ lie on a circle with center $O$ and radius 6, and point $C$ is equidistant from points $A, B$, and $O$. Another circle with center $Q$ and radius 8 is circumscribed around triangle $A C O$. Find $B Q$. Answer: 10
Solution. Since $A Q=O Q=8$ and $A C=O C$, triangles $\triangle A C Q$ and $\triangle O C Q$ are equal. Therefore, points $A$ and $O$ are symmetric with respect to the line $C Q$, so $A O \perp C Q$. Next, $\angle B O Q=\angle B O C+\angle C O Q=\angle A O C+\angle O C Q=\pi / 2$. Therefore, $B Q=\sqrt{B O^{2}+O Q^{2}...
10
Geometry
math-word-problem
Yes
Yes
olympiads
false
2. A motorcycle and a quad bike are driving on a circular road, a quarter of which passes through a forest, and the remaining part - through a field. The motorcycle's speed when driving through the forest is 20 km/h, and through the field - 60 km/h. The quad bike's speed when driving through the forest is 40 km/h, and ...
Answer: The quad will overtake the motorcycle on its $10-\mathrm{th}$ lap while the quad is on its 11-th lap.
10
Logic and Puzzles
math-word-problem
Yes
Yes
olympiads
false
3. In a convex quadrilateral $A B C D$, diagonals $A C$ and $D B$ are perpendicular to sides $D C$ and $A B$ respectively. A perpendicular is drawn from point $B$ to side $A D$, intersecting $A C$ at point $O$. Find $A O$, if $A B=4, O C=6$.
Answer: 2. Solution. Since $\angle A B D=\angle A C D=90^{\circ}$, the quadrilateral is inscribed in a circle with diameter $A D$. Therefore, $\angle A C B=\angle A D B$ - as angles subtending the same arc. Since $B H$ is the altitude in the right $\triangle A B D$, then $\angle A D B=\angle A B H$. Then triangles $A B...
2
Geometry
math-word-problem
Yes
Yes
olympiads
false
8. Masha, bored during a math lesson, performed the following operation on a certain 2015-digit natural number: she discarded the last digit of its decimal representation and added twice the discarded digit to the number obtained by multiplying the remaining number by 3. She then performed the same operation on the res...
Answer: a) 17; b) 09 (the number $100 \ldots 0009$). Solution. a) Let this number be $n$, ending in the digit $y$. Then $n=10 x+y$ after the next operation will become $3 x+2 y$. The equation $10 x+y=3 x+2 y$ is equivalent to $7 x=y$ and, since $y$ is a digit, then $y=7, x=1$. Therefore, $n=17$. b) Note that if the i...
9
Number Theory
math-word-problem
Yes
Yes
olympiads
false
5.1. Solve the inequality $$ 8 \cdot \frac{|x+1|-|x-7|}{|2 x-3|-|2 x-9|}+3 \cdot \frac{|x+1|+|x-7|}{|2 x-3|+|2 x-9|} \leqslant 8 $$ In the answer, write the sum of its integer solutions that satisfy the condition $|x|<120$.
Answer: 6 (solution of the inequality: $\left.\left[\frac{3}{2} ; 3\right) \cup\left(3 ; \frac{9}{2}\right]\right)$. Solution. Let $a$ and $b$ be the first and second terms in the left part of the inequality, respectively. Then $b>0$ and $$ a b=24 \cdot \frac{(x+1)^{2}-(x-7)^{2}}{(2 x-3)^{2}-(2 x-9)^{2}}=24 \cdot \fr...
6
Inequalities
math-word-problem
Yes
Yes
olympiads
false
5.3. Solve the inequality $$ 12 \cdot \frac{|x+10|-|x-20|}{|4 x-25|-|4 x-15|}-\frac{|x+10|+|x-20|}{|4 x-25|+|4 x-15|} \geqslant-6 $$ In the answer, write the sum of its integer solutions that satisfy the condition $|x|<100$.
Answer: 10 (solution of the inequality: $\left.\left[\frac{15}{4} ; 5\right) \cup\left(5 ; \frac{25}{4}\right]\right)$.)
10
Inequalities
math-word-problem
Yes
Yes
olympiads
false
5.4. Solve the inequality $$ 9 \cdot \frac{|x+4|-|x-2|}{|3 x+14|-|3 x-8|}+11 \cdot \frac{|x+4|+|x-2|}{|3 x+14|+|3 x-8|} \leqslant 6 $$ In the answer, write the sum of its integer solutions that satisfy the condition $|x|<110$.
Answer: -6 (solution of the inequality: $[-4 ;-1) \cup(-1 ; 2]$ ).
-6
Inequalities
math-word-problem
Yes
Yes
olympiads
false
10.1. Propose a word problem that reduces to solving the inequality $$ \frac{11}{x+1.5}+\frac{8}{x} \geqslant \frac{12}{x+2}+2 $$ Write the problem statement, its solution, and the answer. Example of the required problem. Points A and B are connected by two roads: one is 19 km long, and the other is 12 km long. At 1...
Answer: no more than 4 km/h.
4
Inequalities
math-word-problem
Yes
Yes
olympiads
false
7.1. (14 points) Find the greatest integer value of $a$ for which the equation $$ (x-a)(x-7)+3=0 $$ has at least one integer root.
Answer: 11. Solution. For the desired values of $a$, the numbers $x-a$ and $x-7$ are integers, and their product is -3, so there are 4 possible cases: $$ \left\{\begin{array} { l } { x - a = 1 , } \\ { x - 7 = - 3 ; } \end{array} \quad \left\{\begin{array} { l } { x - a = 3 , } \\ { x - 7 = - 1 ; } \end{array} \qua...
11
Algebra
math-word-problem
Yes
Yes
olympiads
false
4.1. Find the sum of all roots of the equation $x^{2}-31 x+220=2^{x}\left(31-2 x-2^{x}\right)$.
Answer: 7. Solution. The original equation is equivalent to the equation $\left(x+2^{x}\right)^{2}-31\left(x+2^{x}\right)+220=0 \Leftrightarrow\left[\begin{array}{l}x+2^{x}=11, \\ x+2^{x}=20 .\end{array}\right.$ Each of the equations in this system has no more than one root, as the function $f(x)=x+2^{x}$ is monotonic...
7
Algebra
math-word-problem
Yes
Yes
olympiads
false
4.2. Find the sum of all roots of the equation $x^{2}-41 x+330=3^{x}\left(41-2 x-3^{x}\right)$.
Answer: 5. Instructions. Roots of the equation: 2 and 3.
5
Algebra
math-word-problem
Yes
Yes
olympiads
false
6.1. In an isosceles triangle \(ABC\), one of the angles is equal to the difference of the other two, and one of the angles is twice another. The angle bisectors of angles \(A\), \(B\), and \(C\) intersect the circumcircle of the triangle at points \(L\), \(O\), and \(M\) respectively. Find the area of triangle \(LOM\)...
Answer: 11. Solution. Let in triangle $ABC$ the angle $\alpha$ be equal to the difference of angles $\beta-\gamma$. Since $\alpha+\beta+\gamma=180^{\circ}$, then $\beta-\gamma+\beta+\gamma=180^{\circ}$ and therefore $\beta=90^{\circ}$. If $\beta=90^{\circ}$ is twice one of the angles $\alpha$ or $\gamma$, then the tria...
11
Geometry
math-word-problem
Yes
Yes
olympiads
false
9.4. Find the minimum value of the expression $(\sqrt{2(1+\cos 2 x)}-\sqrt{3-\sqrt{2}} \sin x+1) \cdot(3+2 \sqrt{7-\sqrt{2}} \cos y-\cos 2 y)$. If the answer is not an integer, round it to the nearest integer.
Answer: -9 . Instructions. Exact answer: $2 \sqrt{2}-12$.
-9
Algebra
math-word-problem
Yes
Yes
olympiads
false
10.1. Find the largest integer $k$ such that for at least one natural number $n>1000$, the number $n!=1 \cdot 2 \cdot \ldots \cdot n$ is divisible by $2^{n+k+2}$.
Answer: -3. Solution. The highest power of two that divides $n!$ is the finite sum $\left[\frac{n}{2^{1}}\right]+\left[\frac{n}{2^{2}}\right]+\ldots \leq \frac{n}{2^{1}}+\frac{n}{2^{2}}+\ldots<n$, so it does not exceed $n-1$. At the same time, the equality of this power to the value $n-1$ is achieved at powers of two (...
-3
Number Theory
math-word-problem
Yes
Yes
olympiads
false
9. A set of natural numbers is called bad if it is possible to select several numbers from it such that their sum equals 2012. Find the smallest such $n$ that the numbers $503, 504, \ldots, 2011$ can be partitioned into $n$ sets such that none of these sets are bad.
Answer: $n=2$. Solution: We will show that the given set can be divided into two subsets, neither of which are bad. Consider the sets $M_{1}=\{503,504, \ldots, 671\}$, $M_{2}=\{672,673, \ldots, 1006\}$, $M_{3}=\{1007,1008, \ldots, 1340\}$, $M_{4}=\{1341,1342, \ldots, 2011\}$, and show that $M_{1} \cup M_{3}$ and $M_{2...
2
Combinatorics
math-word-problem
Yes
Yes
olympiads
false
2.1.1. (2 points) Find the greatest value of $x$ that satisfies the inequality $$ \left(6+5 x+x^{2}\right) \sqrt{2 x^{2}-x^{3}-x} \leqslant 0 $$
Answer: 1. Solution. $$ \left[\begin{array} { c } { 2 x ^ { 2 } - x ^ { 3 } - x = 0 ; } \\ { \{ \begin{array} { c } { 2 x ^ { 2 } - x ^ { 3 } - x > 0 ; } \\ { 6 + 5 x + x ^ { 2 } \leqslant 0 ; } \end{array} } \end{array} \Longleftrightarrow \left[\begin{array} { l } { - x ( x - 1 ) ^ { 2 } = 0 ; } \\ { \{ \begin{a...
1
Inequalities
math-word-problem
Yes
Yes
olympiads
false
3.3.1. (12 points) Simplify the expression $$ \left(\frac{2}{\sqrt[3]{3}}+3\right)-\left(\frac{\sqrt[3]{3}+1}{2}-\frac{1}{\sqrt[3]{9}+\sqrt[3]{3}+1}-\frac{2}{1-\sqrt[3]{3}}\right): \frac{3+\sqrt[3]{9}+2 \sqrt[3]{3}}{2} $$ Answer: 3.
Solution. Let's introduce the notation $a=\sqrt[3]{3}$. Then the expression transforms to $$ \left(\frac{2}{a}+3\right)-\left(\frac{a+1}{a^{3}-1}-\frac{1}{a^{2}+a+1}-\frac{2}{1-a}\right): \frac{a^{3}+a^{2}+2 a}{a^{3}-1} $$ and after simplifications and performing the division, it transforms to $\left(\frac{2}{a}+3\ri...
3
Algebra
math-word-problem
Yes
Yes
olympiads
false
4.2.1. (12 points) Every morning, each member of the Ivanov family drinks an 180-gram cup of coffee with milk. The amount of milk and coffee in their cups varies. Masha Ivanova found out that she drank $\frac{2}{9}$ of all the milk consumed that morning and $\frac{1}{6}$ of all the coffee consumed that morning. How man...
Answer: 5. Solution. Let there be $x$ (for example, grams) of milk and $y$ grams of coffee, and $n$ people in the family. Since each family member drank the same amount of coffee with milk, then $\left(\frac{2 x}{9}+\frac{y}{6}\right) n=$ $=x+y \Leftrightarrow(4 x+3 y) n=18 x+18 y \Leftrightarrow 2 x(2 n-9)=3 y(6-n)$....
5
Algebra
math-word-problem
Yes
Yes
olympiads
false
5.3.1. (12 points) Among all possible triangles $ABC$ such that $BC=2 \sqrt[4]{3}, \angle BAC=\frac{\pi}{3}$, find the one with the maximum area. What is this area?
Answer: 3. Solution. The locus of points from which the segment $B C$ is "seen" at an angle $\alpha$ consists of arcs of two circles, from the centers of which the segment $B C$ is "seen" at an angle $2 \pi-2 \alpha$. The points on these arcs that are farthest from the segment are their midpoints. Therefore, the desir...
3
Geometry
math-word-problem
Yes
Yes
olympiads
false
7.2.1. (12 points) Calculate the value of the expression $\arccos \frac{\sqrt{6}+1}{2 \sqrt{3}}-\arccos \sqrt{\frac{2}{3}}$. Write the obtained expression in the form $\frac{a \pi}{b}$, where $a$ and $b$ are integers, and are coprime, and specify the value of $|a-b|$. #
# Answer: 7. Solution. Since $\alpha=\arccos \frac{\sqrt{6}+1}{2 \sqrt{3}} \in\left(0 ; \frac{\pi}{2}\right)$ and $\beta=\arccos \sqrt{\frac{2}{3}} \in\left(0 ; \frac{\pi}{2}\right)$, then $A=\alpha-\beta \in\left(-\frac{\pi}{2} ; \frac{\pi}{2}\right)$. Therefore, $\sin A=\sin \alpha \cos \beta-\cos \alpha \sin \beta$...
7
Algebra
math-word-problem
Yes
Yes
olympiads
false
7.4.1. (12 points) How many integer roots of the equation $$ \cos 2 \pi x + \cos \pi x = \sin 3 \pi x + \sin \pi x $$ lie between the roots of the equation $x^{2} + 10 x - 17 = 0$?
# Answer: 7. Solution. If $x=2 k, k \in \mathbb{Z}$, then $\cos 2 \pi x+\cos \pi x=\cos 4 \pi k+\cos 2 \pi k=2, \sin 3 \pi x+\sin \pi x=$ $\sin 6 \pi k+\sin 2 \pi k=0$, so there are no even numbers among the roots of the first equation. If, however, $x=2 k+1, k \in \mathbb{Z}$, then $\cos 2 \pi x+\cos \pi x=\cos (4 \...
7
Algebra
math-word-problem
Yes
Yes
olympiads
false
10.2.1. (12 points) Find the greatest integer value of $a$ for which the equation $$ \sqrt[3]{x^{2}-(a+7) x+7 a}+\sqrt[3]{3}=0 $$ has at least one integer root.
Answer: 11. Solution. For the desired values of $a$, the numbers $x-a$ and $x-7$ are integers, and their product is -3, so there are 4 possible cases: $$ \left\{\begin{array} { l } { x - a = 1 , } \\ { x - 7 = - 3 ; } \end{array} \quad \left\{\begin{array} { l } { x - a = 3 , } \\ { x - 7 = - 1 ; } \end{array} \qua...
11
Algebra
math-word-problem
Yes
Yes
olympiads
false
10.3.1. (12 points) The curve given by the equation $y=2^{p} x^{2}+5 p x-2^{p^{2}}$ intersects the $O x$ axis at points $A$ and $B$, and the $O y$ axis at point $C$. Find the sum of all values of the parameter $p$ for which the center of the circle circumscribed around triangle $A B C$ lies on the $O x$ axis.
Answer: -1. Solution. Let $x_{1}$ and $x_{2}$ be the roots of the quadratic trinomial $a x^{2}+b x+c (c \neq 0)$, the graph of which intersects the $O x$ axis at points $A$ and $B$, and the $O y$ axis at point $C$. Then $A\left(x_{1} ; 0\right), B\left(x_{2} ; 0\right), C(0 ; c)$. The fact that the center of the circl...
-1
Algebra
math-word-problem
Yes
Yes
olympiads
false
10.4.1. (12 points) Find all pairs of integers $(x, y)$ that are solutions to the equation $$ 7 x y-13 x+15 y-37=0 \text {. } $$ In your answer, indicate the sum of the found values of $x$.
Answer: 4. Solution. Multiplying both sides of the equation by 7, we get $$ 7 \cdot 7 x y - 13 \cdot 7 x + 15 \cdot 7 y - 37 \cdot 7 = 0 $$ Rewriting this equation, we have $$ (7 x + 15)(7 y - 13) = 64 $$ If $x$ and $y$ are integers, then the numbers $7 x + 15$ and $7 y - 13$ are also integers and leave a remainde...
4
Algebra
math-word-problem
Yes
Yes
olympiads
false
8. Find the minimum value of the discriminant of a quadratic trinomial, the graph of which has no common points with the regions located below the x-axis and above the graph of the function $y=\frac{1}{\sqrt{1-x^{2}}}$.
Answer: -4. Solution. Since the discriminant of a quadratic trinomial $$ D=b^{2}-4 a c $$ we will find the maximum value of the product $a c$. Since for all $x$ the inequality $a x^{2}+b x+c \geqslant 0$ holds, then $a \geqslant 0, c \geqslant 0$. Let $$ f(x)=\frac{1}{\sqrt{1-x^{2}}}-\left(a x^{2}+b x+c\right) $$ ...
-4
Algebra
math-word-problem
Yes
Yes
olympiads
false
9. In triangle $ABC$, the bisectors $AL, BM$, and $CN$ are drawn, and $\angle ANM = \angle ALC$. Find the radius of the circumcircle of triangle $LMN$, two sides of which are equal to 3 and 4.
Answer: 2 Solution. The following statement is true: Let $A L, B M$ and $C N$ be the bisectors of the internal angles of a triangle. If $\angle A N M = \angle A L C$, then $\angle B C A = 120^{\circ}$. Proof. Draw $M D \| A L$, then $\angle C M D = \frac{\alpha}{2}$. The angle $\angle A L C$ is an external angle of...
2
Geometry
math-word-problem
Yes
Yes
olympiads
false
Problem 4. The Dursleys are hiding Harry Potter on an island that is 9 km from the shore. The shore is straight. On the shore, 15 kilometers from the point on the shore closest to the island, Hagrid is on a magical motorcycle and wants to reach Harry as quickly as possible. The motorcycle travels along the shore at a s...
# Answer: 3. Solution. Let $A$ be the point from which Hagrid starts, $B$ be the island, and $C$ be the point where the motorcycle crashes into the sea. The travel time is $t=\frac{A C}{50}+\frac{B C}{40}=p A C+q B C=q\left(\frac{p}{q} A C+B C\right)$, where $p=\frac{1}{50}, q=\frac{1}{40}$. Thus, we aim to minimize $...
3
Algebra
math-word-problem
Yes
Yes
olympiads
false
10.1. Propose a word problem that reduces to solving the inequality $$ \frac{11}{x+1.5}+\frac{8}{x} \geqslant \frac{12}{x+2}+2 $$ Write the problem statement, its solution, and the answer. Example of the required problem. Points A and B are connected by two roads: one is 19 km long, and the other is 12 km long. At 1...
Answer: no more than 4 km/h.
4
Inequalities
math-word-problem
Yes
Yes
olympiads
false
1.1. (2 points) How many roots does the equation $x^{2}-x \sqrt{5}+\sqrt{2}=0$ have?
Answer: 0. Solution. Since $D=5-4 \sqrt{2}<0$, the equation has no roots.
0
Algebra
math-word-problem
Yes
Yes
olympiads
false
4.1. (12 points) In trapezoid $A B C D$ with bases $A D=17$ and $B C=9$, points $E$ and $F$ are marked on the bases respectively such that $M E N F$ is a rectangle, where $M$ and $N$ are the midpoints of the diagonals of the trapezoid. Find the length of segment $E F$.
Answer: 4. Solution. The segment connecting the midpoints of the diagonals of a trapezoid is equal to half the difference of the bases, so $M N=\frac{A D-B C}{2}=4$. Since $M E N F$ is a rectangle, its diagonals are equal. Therefore, $E F=M N=4$.
4
Geometry
math-word-problem
Yes
Yes
olympiads
false
3. Find the minimum value of the expression $\frac{1}{1-x^{2}}+\frac{4}{4-y^{2}}$ under the conditions $|x|<1,|y|<2$ and $x y=1$. Answer: 4.
Solution. Using the inequality between the arithmetic mean and the geometric mean, under the given conditions on $x$ and $y$, we obtain $$ \frac{1}{1-x^{2}}+\frac{4}{4-y^{2}} \geqslant 2 \sqrt{\frac{1}{1-x^{2}} \cdot \frac{4}{4-y^{2}}}=\frac{4}{\sqrt{5-4 x^{2}-y^{2}}}=\frac{4}{\sqrt{1-(2 x-y)^{2}}} \geqslant 4 $$ and...
4
Algebra
math-word-problem
Yes
Yes
olympiads
false
4. Having walked $2 / 5$ of the length of a narrow bridge, a pedestrian noticed that a car was approaching the bridge from behind. Then he walked back and met the car at the beginning of the bridge. If the pedestrian had continued walking forward, the car would have caught up with him at the end of the bridge. Find the...
Answer: 5. Solution. In the time $t$ that the pedestrian walked towards the car until they met at the beginning of the bridge, he covered $2 / 5$ of the bridge's length. Therefore, if the pedestrian continued walking forward, in time $t$ he would have covered another $2 / 5$ of the bridge's length, and he would have $...
5
Algebra
math-word-problem
Yes
Yes
olympiads
false
7. How many solutions does the equation \[ \frac{1}{(x-1)^{2}}+\frac{1}{(x-2)^{2}}=\frac{2}{x^{2}} ? \] ![](https://cdn.mathpix.com/cropped/2024_05_06_948de1dbe9747fa89f7eg-2.jpg?height=446&width=645&top_left_y=131&top_left_x=1322)
Answer: 1. Solution. Let's introduce the functions $f(x)=\frac{1}{(x-1)^{2}}+\frac{1}{(x-2)^{2}}$ and $g(x)=\frac{2}{x^{2}}$. For $x<0$, both functions $f$ and $g$ are positive, but $f(x)$ increases from $+\infty$ to 2 (not inclusive), since $f^{\prime}(x)=\frac{-2}{(x-1)^{3}}-\frac{2}{(x-2)^{3}}<0 \quad \text { for ...
1
Algebra
math-word-problem
Yes
Yes
olympiads
false
8. Given three points, the distances between which are 4, 6, and 7. How many pairwise distinct triangles exist for which each of these points is either a vertex or the midpoint of a side?
Answer: 11. Solution. Let's list all the constructions of triangles that satisfy the condition of the problem, with | | Description of the triangle | | Side lengths | | :---: | :---: | :---: | :---: | | â„–1 | All points are vertices | | $4,6,7$ | | | One point is a vertex, two are midpoints of sides | | | | â„–2 |...
11
Geometry
math-word-problem
Yes
Yes
olympiads
false
5. The divisors of a natural number $n$ (including $n$ and 1), which has more than three divisors, were listed in ascending order: $1=d_{1}<d_{2} \ldots<d_{k}=n$. The differences $u_{1}=d_{2}-d_{1}, u_{2}=d_{3}-d_{2}, \ldots, u_{k-1}=d_{k}-d_{k-1}$ turned out to be such that $u_{2}-u_{1}=u_{3}-u_{2}=\ldots=u_{k-1}-u_{k...
Answer: 10. Solution: Let $n$ be odd. Then $u_{k-1}=d_{k}-d_{k-1} \geq n-n / 3=2 n / 3$. In this case, $u_{k-2}=d_{k-1}-d_{k-2}n / 3$, but $u_{k-1}-u_{k-2}=u_{k-2}-u_{k-3}<u_{k-2}<n / 3$ - a contradiction. In the case of even $n$, we get $u_{k-1}=d_{k}-d_{k-1}=n / 2, u_{k-2}=d_{k-1}-d_{k-2}=n / 2-d_{k-2}$, so $u_{k-1}-...
10
Number Theory
math-word-problem
Yes
Yes
olympiads
false
5. From the odd natural numbers from 1 to 47, 12 fractions less than 1 were formed, using each number exactly once. The resulting fractions were divided into groups of equal values. What is the smallest number of groups that could have been obtained? (I. Rubanov)
Answer: 7. Solution: Evaluation. A fraction containing at least one of the prime numbers 17, 19, 23, 29, 31, 37, 41, 43, 47 cannot equal any of our other fractions, because already $17 \cdot 3 > 47$. Since there are no more than nine such "lonely" fractions, among the constructed fractions there are some that are not e...
7
Number Theory
math-word-problem
Yes
Yes
olympiads
false
7. For what largest $n$ can the numbers $1,2, \ldots, 14$ be colored red and blue so that for any number $k=1,2, \ldots, n$ there exist a pair of blue numbers whose difference is $k$, and a pair of red numbers whose difference is also $k$? (D. Khramtsov)
Answer: $n=11$. Solution. Obviously, $\mathrm{n} \leq 12$, since there is only one pair of numbers with a difference of 13. Suppose the required is possible for $n=12$. The number 12 can be represented as the difference of numbers from 1 to 14 in exactly two ways: 13-1 and 14-2. Let the number 1 be red for definiteness...
11
Combinatorics
math-word-problem
Yes
Yes
olympiads
false
7. For four different integers, all their pairwise sums and pairwise products were calculated and written on the board. What is the smallest number of different numbers that could have appeared on the board? (I. Rubanov)
Answer: 6. Solution: If we take the numbers $-1,0,1,2$, it is easy to verify that each of the numbers written on the board will be equal to -2, -1, 0, 1, 2, or 3 - a total of 6 different values. We will show that fewer than six different numbers could not appear on the board. Let the taken numbers be $ac+d$. If $ac+d$....
6
Algebra
math-word-problem
Yes
Yes
olympiads
false
2. In triangle $ABC$, $AC=1$, $AB=2$, $O$ is the point of intersection of the angle bisectors. A segment passing through point $O$ parallel to side $BC$ intersects sides $AC$ and $AB$ at points $K$ and $M$ respectively. Find the perimeter of triangle $AKM$.
Answer: 3. Solution. Note that $\angle K C O=\angle B C O=\angle K O C$ (alternate interior angles). Therefore, $O K=K C$. Similarly, $B M=O M$. Therefore, $A K+A M+K M=A K+K C+A M+B M=3$.
3
Geometry
math-word-problem
Yes
Yes
olympiads
false
6. Viewers rate a movie with an integer number of points from 0 to 10. At any given time, the movie's rating is calculated as the sum of all the given ratings divided by their number. At some point in time $T$, the rating was an integer, and then with each new voting viewer, it decreased by one. What is the maximum num...
Answer: 5. Solution: Consider a moment when the rating has decreased by 1. Suppose that before this, $n$ people had voted, and the rating was an integer $x$. This means the sum of the scores was $n x$. Let the next viewer give a score of $y$. Then the sum of the scores becomes $n x + y = (n + 1)(x - 1)$, from which we ...
5
Number Theory
math-word-problem
Yes
Yes
olympiads
false
1. Given two numbers (not necessarily integers), not equal to 0. If each of them is increased by one, their product will double. By what factor will their product increase if each of the original numbers is squared and then decreased by one? (D. Shiryayev, I. Rubanov)
Answer. 4 times. Solution. Let the numbers be denoted by $a$ and $b$. According to the condition, $(a+1)(b+1)=a b+a+b+1=2 a b$. By combining like terms in the last equality, we get $a b-a-b-1=0$, from which $(a-1)(b-1)=a b-a-b+1=2$ and $\left(a^{2}-1\right)\left(b^{2}-1\right)=(a-1)(b-1)(a+1)(b+1)=2 \cdot 2 a b=4 a b$.
4
Algebra
math-word-problem
Yes
Yes
olympiads
false
5. In a football tournament where each team played against each other once, teams $A$, B, V, G, D, and E participated. Teams received 3 points for a win, 1 point for a draw, and 0 points for a loss. In the end, it turned out that teams $A$, B, V, G, and D each scored 7 points. What is the maximum number of points that ...
Answer: 7 points. Solution: In a match where one of the teams won, the teams together score 3 points, in a match that ended in a draw - 2 points. Since 7 is not divisible by 3, the team that scored 7 points must have at least one draw. Since there are five such teams, there were at least three draws in the tournament. ...
7
Combinatorics
math-word-problem
Yes
Yes
olympiads
false
4. Before starting to solve the problem, Kolya looked at the clock. It was two o'clock. Spending exactly an hour on solving it, Kolya looked at the clock again and noticed that the angle between the hour and minute hands remained the same. When did Kolya start solving the problem?
Answer. At 1 hour $8^{2} /{ }_{11}$ min or at 1 hour $40^{10} / 11$ min. Solution. Let it be $x$ minutes past two when Petya looked at the clock. Since the minute hand moves $6^{\circ}$ per minute, and the hour hand $-0,5^{\circ}$, the hour hand at this moment formed an angle of $30^{\circ}+0,5 x^{\circ}$ with the 12 o...
1
Logic and Puzzles
math-word-problem
Yes
Yes
olympiads
false
5. For what largest $p$ does there exist a convex $n$-gon in which the lengths of the diagonals take on no more than two distinct values? (I. Rubanov)
Answer. For $n=7$. Solution. Example. A regular heptagon. It has diagonals of exactly two types: connecting vertices one apart and two apart. Evaluation. Let $A B$ be a side of a convex polygon $M$, which has diagonals of only two possible lengths $x$ and $y$. Then for any vertex $C$, not adjacent to $A$ and $B$, the s...
7
Geometry
math-word-problem
Yes
Yes
olympiads
false
1. Vintik and Shpuntik built a machine called "Tug-Push," which moves forward on syrup with a fuel consumption of Zl/km, and backward on orange juice with a fuel consumption of 5l/km. Leaving home, they drove the machine in turns. Vintik drove 12 km in both directions. Shpuntik drove forward half as much as Vintik, and...
Answer: 9 km. Solution: Let Vintik travel $2 x$ km forward and $y$ km back, then $2 x+y=12$ and $9 x+15 y=75$ (since together they traveled $3 x$ km forward and $3 y$ km back). Solving the system, we get $x=5, y=2$. It remains to calculate $3 x-3 y=9$.
9
Algebra
math-word-problem
Yes
Yes
olympiads
false
2. A rectangular grid with sides 629 and 630 is cut into several squares (all cuts follow the grid lines). What is the smallest number of squares with an odd side that can be in such a partition? Don't forget to explain why there cannot be a smaller number of squares with an odd side in the partition.
Answer: Two. Solution. An example when there are exactly two squares: two squares with a side of 315 adjoin the side of the rectangle with a length of 630, and the remaining rectangle $630 \times 314$ is cut into squares $2 \times 2$. A smaller number of squares with an odd side cannot be: to each of the sides of lengt...
2
Number Theory
math-word-problem
Yes
Yes
olympiads
false
8. We will call two numbers almost equal to each other if they are equal to each other or differ from each other by no more than one. A rectangular grid with sides of natural numbers a and b is such that it is impossible to cut out a rectangle along the grid lines, the area of which is almost equal to half the area of ...
Answer: 4. Solution: If one of the sides of the rectangle is even, a rectangle of half the area can be cut from it along the midline. Therefore, it is sufficient to consider the case where both sides are odd. In this case, $|b-a|$ is even. If $|b-a|=0$, then $a=b=2n+1$, half the area of the rectangle is $2n^2+2n+0.5$, ...
4
Number Theory
math-word-problem
Yes
Yes
olympiads
false
5. On each of five cards, a number is written. The cards lie on the table numbers down. We can, by paying a ruble, point to any three cards, and we will be told the sum of the numbers written on them. For what minimum price can we surely find out the sum of all five numbers? (I. Rubanov)
Answer: For 4 rubles. Solution: Let the numbers written be $a, b, c, d, e$. We ask about the sums $a+b+c, a+b+d$, $a+b+e, c+d+e$. Then, by adding the first three sums and subtracting the fourth from the result, we get $3(a+b)$, then $a+b$ and, by adding $c+d+e$ to the result, the sum of all five numbers. Suppose we ma...
4
Logic and Puzzles
math-word-problem
Yes
Yes
olympiads
false
2. On the side AC of triangle ABC with an angle of 120 degrees at vertex B, points D and E are marked such that $AD = AB$ and $CE = CB$. A perpendicular $DF$ is dropped from point D to the line BE. Find the ratio $BD / DF$.
Answer. 2. Solution. Let $\angle C A B=\alpha, \angle A C B=\beta$. Since $A D=A B$ and $C E=C B$, we have $\angle D B E=\angle D B A+\angle E B C-\angle A B C=\left(180^{\circ}-\alpha\right) / 2+\left(180^{\circ}-\beta\right) / 2-120^{\circ}=60^{\circ}-(\alpha+\beta) / 2=30^{\circ}$. Thus, in the right triangle $B F...
2
Geometry
math-word-problem
Yes
Yes
olympiads
false