problem stringlengths 10 5.15k | answer dict |
|---|---|
Let $a_1=1$ and $a_n=n(a_{n-1}+1)$ for all $n\ge 2$ . Define : $P_n=\left(1+\frac{1}{a_1}\right)...\left(1+\frac{1}{a_n}\right)$ Compute $\lim_{n\to \infty} P_n$ | {
"answer": "e",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
A sweater costs 160 yuan, it was first marked up by 10% and then marked down by 10%. Calculate the current price compared to the original. | {
"answer": "0.99",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Let the internal angles $A$, $B$, $C$ of $\triangle ABC$ be opposite to the sides $a$, $b$, $c$ respectively, and $c\cos B= \sqrt {3}b\sin C$.
$(1)$ If $a^{2}\sin C=4 \sqrt {3}\sin A$, find the area of $\triangle ABC$;
$(2)$ If $a=2 \sqrt {3}$, $b= \sqrt {7}$, and $c > b$, the midpoint of side $BC$ is $D$, find the length of $AD$. | {
"answer": "\\sqrt {13}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
In $\triangle ABC$, it is known that $AB=2$, $AC=3$, and $A=60^{\circ}$.
$(1)$ Find the length of $BC$;
$(2)$ Find the value of $\sin 2C$. | {
"answer": "\\frac{4\\sqrt{3}}{7}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given vectors $\overrightarrow{a}=(\sin x, \sqrt{3}\cos x)$, $\overrightarrow{b}=(-1,1)$, and $\overrightarrow{c}=(1,1)$, where $x \in [0, \pi]$.
(1) If $(\overrightarrow{a} + \overrightarrow{b}) \parallel \overrightarrow{c}$, find the value of $x$;
(2) If $\overrightarrow{a} \cdot \overrightarrow{b} = \frac{1}{2}$, find the value of the function $\sin \left(x + \frac{\pi}{6}\right)$. | {
"answer": "\\frac{\\sqrt{15}}{4}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given a geometric sequence \(\{a_n\}\) with the sum of the first \(n\) terms \(S_n\) such that \(S_n = 2^n + r\) (where \(r\) is a constant), let \(b_n = 2(1 + \log_2 a_n)\) for \(n \in \mathbb{N}^*\).
1. Find the sum of the first \(n\) terms of the sequence \(\{a_n b_n\}\), denoted as \(T_n\).
2. If for any positive integer \(n\), the inequality \(\frac{1 + b_1}{b_1} \cdot \frac{1 + b_2}{b_2} \cdots \cdot \frac{1 + b_n}{b_n} \geq k \sqrt{n + 1}\) holds, determine \(k\). | {
"answer": "\\frac{3}{4} \\sqrt{2}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the function $f(x)= \frac{x}{4} + \frac{a}{x} - \ln x - \frac{3}{2}$, where $a \in \mathbb{R}$, and the curve $y=f(x)$ has a tangent at the point $(1,f(1))$ which is perpendicular to the line $y=\frac{1}{2}x$.
(i) Find the value of $a$;
(ii) Determine the intervals of monotonicity and the extreme values for the function $f(x)$. | {
"answer": "-\\ln 5",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
The line $2x+ay-2=0$ is parallel to the line $ax+(a+4)y-4=0$. Find the value of $a$. | {
"answer": "-2",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the ellipse $C$: $\frac{x^{2}}{a^{2}}+ \frac{y^{2}}{b^{2}}=1 (a > b > 0)$ passing through the point $E(\sqrt{3}, 1)$, with an eccentricity of $\frac{\sqrt{6}}{3}$, and $O$ as the coordinate origin.
(I) Find the equation of the ellipse $C$;
(II) If point $P$ is a moving point on the ellipse $C$, and the perpendicular bisector of segment $AP$, where $A(3, 0)$, intersects the $y$-axis at point $B$, find the minimum value of $|OB|$. | {
"answer": "\\sqrt{6}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
If the tangent line of the curve $y=\ln x$ at point $P(x_{1}, y_{1})$ is tangent to the curve $y=e^{x}$ at point $Q(x_{2}, y_{2})$, then $\frac{2}{{x_1}-1}+x_{2}=$____. | {
"answer": "-1",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
For any number $y$, define the operations $\&y = 2(7-y)$ and $\&y = 2(y-7)$. What is the value of $\&(-13\&)$? | {
"answer": "66",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given that the function $f(x) = x^3 + ax^2 + bx + a^2$ has an extreme value of 10 at $x = 1$, find the slope of the tangent to the function at $x = 2$. | {
"answer": "17",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
The number of students in James' graduating class is greater than 100 but fewer than 200 and is 1 less than a multiple of 4, 2 less than a multiple of 5, and 3 less than a multiple of 6. How many students are in James' graduating class? | {
"answer": "183",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
A total of 6 letters are used to spell the English word "theer". Calculate the probability that the person spells this English word incorrectly. | {
"answer": "\\frac{59}{60}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
A sequence $(c_n)$ is defined as follows: $c_1 = 1$, $c_2 = \frac{1}{3}$, and
\[c_n = \frac{2 - c_{n-1}}{3c_{n-2}}\] for all $n \ge 3$. Find $c_{100}$. | {
"answer": "\\frac{1}{3}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Cagney can frost a cupcake every 25 seconds and Lacey can frost a cupcake every 35 seconds. If Lacey spends the first minute exclusively preparing frosting and then both work together to frost, determine the number of cupcakes they can frost in 10 minutes. | {
"answer": "37",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
The distance traveled by the center \( P \) of a circle with radius 1 as it rolls inside a triangle with side lengths 6, 8, and 10, returning to its initial position. | {
"answer": "12",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the hyperbola with the equation $\frac{x^{2}}{4} - \frac{y^{2}}{9} = 1$, where $F\_1$ and $F\_2$ are its foci, and point $M$ lies on the hyperbola.
(1) If $\angle F\_1 M F\_2 = 90^{\circ}$, find the area of $\triangle F\_1 M F\_2$.
(2) If $\angle F\_1 M F\_2 = 60^{\circ}$, what is the area of $\triangle F\_1 M F\_2$? If $\angle F\_1 M F\_2 = 120^{\circ}$, what is the area of $\triangle F\_1 M F\_2$? | {
"answer": "3 \\sqrt{3}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
What is the smallest positive integer $k$ such that the number $\textstyle\binom{2k}k$ ends in two zeros? | {
"answer": "13",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given a sequence $\{a_n\}$, where $a_{n+1} + (-1)^n a_n = 2n - 1$, calculate the sum of the first 12 terms of $\{a_n\}$. | {
"answer": "78",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
What is the product of the solutions of the equation $45 = -x^2 - 4x?$ | {
"answer": "-45",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Two identical cylindrical containers are connected at the bottom by a small tube with a tap. While the tap was closed, water was poured into the first container, and oil was poured into the second one, so that the liquid levels were the same and equal to $h = 40$ cm. At what level will the water in the first container settle if the tap is opened? The density of water is 1000 kg/$\mathrm{m}^3$, and the density of oil is 700 kg/$\mathrm{m}^3$. Neglect the volume of the connecting tube. Give the answer in centimeters. | {
"answer": "16.47",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Consider the 100th, 101st, and 102nd rows of Pascal's triangle, denoted as sequences $(p_i)$, $(q_i)$, and $(r_i)$ respectively. Calculate:
\[
\sum_{i = 0}^{100} \frac{q_i}{r_i} - \sum_{i = 0}^{99} \frac{p_i}{q_i}.
\] | {
"answer": "\\frac{1}{2}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given that $f(x)$ is a function defined on $\mathbb{R}$ with a period of $2$, in the interval $[1,3]$, $f(x)= \begin{cases}x+ \frac {a}{x}, & 1\leqslant x < 2 \\ bx-3, & 2\leqslant x\leqslant 3\end{cases}$, and $f( \frac {7}{2})=f(- \frac {7}{2})$, find the value of $15b-2a$. | {
"answer": "41",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Several points were marked on a line, and then two additional points were placed between each pair of neighboring points. This procedure was repeated once more with the entire set of points. Could there have been 82 points on the line as a result? | {
"answer": "10",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given a circle O with a radius of 6, the length of chord AB is 6.
(1) Find the size of the central angle α corresponding to chord AB;
(2) Find the arc length l and the area S of the sector where α is located. | {
"answer": "6\\pi",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
In the diagram, $\mathrm{ABCD}$ is a right trapezoid with $\angle \mathrm{DAB} = \angle \mathrm{ABC} = 90^\circ$. A rectangle $\mathrm{ADEF}$ is constructed externally along $\mathrm{AD}$, with an area of 6.36 square centimeters. Line $\mathrm{BE}$ intersects $\mathrm{AD}$ at point $\mathrm{P}$, and line $\mathrm{PC}$ is then connected. The area of the shaded region in the diagram is: | {
"answer": "3.18",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Consider the matrix
\[\mathbf{N} = \begin{pmatrix} 2x & -y & z \\ y & x & -2z \\ y & -x & z \end{pmatrix}\]
and it is known that $\mathbf{N}^T \mathbf{N} = \mathbf{I}$. Find $x^2 + y^2 + z^2$. | {
"answer": "\\frac{2}{3}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Let $f$ be a quadratic function which satisfies the following condition. Find the value of $\frac{f(8)-f(2)}{f(2)-f(1)}$ .
For two distinct real numbers $a,b$ , if $f(a)=f(b)$ , then $f(a^2-6b-1)=f(b^2+8)$ . | {
"answer": "13",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given that $\binom{20}{13} = 77520$, $\binom{20}{14} = 38760$ and $\binom{18}{12} = 18564$, find $\binom{19}{13}$. | {
"answer": "27132",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Find the number of positive integers $n$ that satisfy
\[(n - 2)(n - 4)(n - 6) \dotsm (n - 98) < 0.\] | {
"answer": "24",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Four red beads, two white beads, and one green bead are placed in a line in random order. What is the probability that no two neighboring beads are the same color?
A) $\frac{1}{15}$
B) $\frac{2}{15}$
C) $\frac{1}{7}$
D) $\frac{1}{30}$
E) $\frac{1}{21}$ | {
"answer": "\\frac{2}{15}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given that the hyperbola $C_2$ and the ellipse $C_1$: $$\frac {x^{2}}{4} + \frac {y^{2}}{3} = 1$$ have the same foci, the eccentricity of the hyperbola $C_2$ when the area of the quadrilateral formed by their four intersection points is maximized is ______. | {
"answer": "\\sqrt {2}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given that the equations of the two asymptotes of a hyperbola are $y = \pm \sqrt{2}x$ and it passes through the point $(3, -2\sqrt{3})$.
(1) Find the equation of the hyperbola;
(2) Let $F$ be the right focus of the hyperbola. A line with a slope angle of $60^{\circ}$ intersects the hyperbola at points $A$ and $B$. Find the length of the segment $|AB|$. | {
"answer": "16 \\sqrt{3}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
The median \(AD\) of an acute-angled triangle \(ABC\) is 5. The orthogonal projections of this median onto the sides \(AB\) and \(AC\) are 4 and \(2\sqrt{5}\), respectively. Find the side \(BC\). | {
"answer": "2 \\sqrt{10}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Twelve standard 6-sided dice are rolled. What is the probability that exactly two of the dice show a 1? Express your answer as a decimal rounded to the nearest thousandth. | {
"answer": "0.295",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
In the number $56439.2071$, the value of the place occupied by the digit 6 is how many times as great as the value of the place occupied by the digit 2? | {
"answer": "10,000",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
A television station is set to broadcast 6 commercials in a sequence, which includes 3 different business commercials, 2 different World Expo promotional commercials, and 1 public service commercial. The last commercial cannot be a business commercial, and neither the World Expo promotional commercials nor the public service commercial can play consecutively. Furthermore, the two World Expo promotional commercials must also not be consecutive. How many different broadcasting orders are possible? | {
"answer": "36",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given \(\frac{\sin (\beta+\gamma) \sin (\gamma+\alpha)}{\cos \alpha \cos \gamma}=\frac{4}{9}\), find the value of \(\frac{\sin (\beta+\gamma) \sin (\gamma+\alpha)}{\cos (\alpha+\beta+\gamma) \cos \gamma}\). | {
"answer": "\\frac{4}{5}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
In triangle $ABC$, the sides opposite to the internal angles $A$, $B$, and $C$ are denoted as $a$, $b$, and $c$, respectively. It is given that $a=b\cos C+c\sin B$.
$(1)$ Find $B$;
$(2)$ If $b=2$, find the maximum area of $\triangle ABC$. | {
"answer": "\\sqrt {2}+1",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given a geometric series \(\left\{a_{n}\right\}\) with the sum of its first \(n\) terms denoted by \(S_{n}\), and satisfying the equation \(S_{n}=\frac{\left(a_{n}+1\right)^{2}}{4}\), find the value of \(S_{20}\). | {
"answer": "400",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Find the natural number $A$ such that there are $A$ integer solutions to $x+y\geq A$ where $0\leq x \leq 6$ and $0\leq y \leq 7$ .
*Proposed by David Tang* | {
"answer": "10",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the function $f(x) = \cos(\omega x - \frac{\pi}{3}) - \cos(\omega x)$ $(x \in \mathbb{R}, \omega$ is a constant, and $1 < \omega < 2)$, the graph of function $f(x)$ is symmetric about the line $x = \pi$.
(Ⅰ) Find the smallest positive period of the function $f(x)$.
(Ⅱ) In $\triangle ABC$, the sides opposite angles $A$, $B$, and $C$ are $a$, $b$, and $c$ respectively. If $a=1$ and $f(\frac{3}{5}A) = \frac{1}{2}$, find the maximum area of $\triangle ABC$. | {
"answer": "\\frac{\\sqrt{3}}{4}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Let $p>q$ be primes, such that $240 \nmid p^4-q^4$ . Find the maximal value of $\frac{q} {p}$ . | {
"answer": "2/3",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Let $BCDK$ be a convex quadrilateral such that $BC=BK$ and $DC=DK$ . $A$ and $E$ are points such that $ABCDE$ is a convex pentagon such that $AB=BC$ and $DE=DC$ and $K$ lies in the interior of the pentagon $ABCDE$ . If $\angle ABC=120^{\circ}$ and $\angle CDE=60^{\circ}$ and $BD=2$ then determine area of the pentagon $ABCDE$ . | {
"answer": "\\sqrt{3}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the eccentricity $e= \frac { \sqrt {3}}{2}$ of an ellipse $C: \frac {x^{2}}{a^{2}}+ \frac {y^{2}}{b^{2}}=1 (a>b>0)$ with one of its foci at $F( \sqrt {3} , 0)$,
(I) Find the equation of ellipse C;
(II) Let line $l$, passing through the origin O and not perpendicular to the coordinate axes, intersect curve C at points M and N. Additionally, consider point $A(1, \frac {1}{2})$. Determine the maximum area of △MAN. | {
"answer": "\\sqrt {2}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Consider a 4-by-4 grid where each of the unit squares can be colored either purple or green. Each color choice is equally likely independent of the others. Compute the probability that the grid does not contain a 3-by-3 grid of squares all colored purple. Express your result in the form $\frac{m}{n}$, where $m$ and $n$ are relatively prime positive integers and give the value of $m+n$. | {
"answer": "255",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Let $N$ be the number of ordered pairs of integers $(x, y)$ such that
\[
4x^2 + 9y^2 \le 1000000000.
\]
Let $a$ be the first digit of $N$ (from the left) and let $b$ be the second digit of $N$ . What is the value of $10a + b$ ? | {
"answer": "52",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
The diagram shows a square, its two diagonals, and two line segments, each of which connects two midpoints of the sides of the square. What fraction of the area of the square is shaded?
A) $\frac{1}{8}$
B) $\frac{1}{10}$
C) $\frac{1}{12}$
D) $\frac{1}{16}$
E) $\frac{1}{24}$ | {
"answer": "\\frac{1}{16}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Vaccination is one of the important means to protect one's own and others' health and lives. In order to test the immune effect of a certain vaccine on the $C$ virus, researchers used white rabbits as experimental subjects and conducted the following experiments:<br/>Experiment 1: Select 10 healthy white rabbits, numbered 1 to 10, inject them with the vaccine once, and then expose them to an environment containing the $C$ virus. The results of the experiment showed that four of the white rabbits, numbers 2, 6, 7, and 10, were still infected with the $C$ virus, while the others were not infected.<br/>Experiment 2: The vaccine can be injected a second time, but the time interval between the two injections must be more than three weeks. After injecting the vaccine, if antibodies can be produced in the organism, it is considered effective, and the vaccine's protection period is eight months. Researchers injected the first dose of the vaccine to the white rabbits three weeks after the first dose, and whether the vaccine is effective for the white rabbits is not affected by each other.<br/>$(1)$ In "Experiment 1," white rabbits numbered 1 to 5 form Experiment 1 group, and white rabbits numbered 6 to 10 form Experiment 2 group. Researchers first randomly select one group from the two experimental groups, and then randomly select a white rabbit from the selected group for research. Only one white rabbit is taken out each time, and it is not put back. Find the probability that the white rabbit taken out in the first time is infected given that the white rabbit taken out in the second time is not infected;<br/>$(2)$ If the frequency of white rabbits not infected with the $C$ virus in "Experiment 1" is considered as the effectiveness rate of the vaccine, can the effectiveness rate of a white rabbit after two injections of the vaccine reach 96%? If yes, please explain the reason; if not, what is the minimum effectiveness rate of each vaccine injection needed to ensure that the effectiveness rate after two injections of the vaccine is not less than 96%. | {
"answer": "80\\%",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Find the least positive integer $n$ satisfying the following statement: for eash pair of positive integers $a$ and $b$ such that $36$ divides $a+b$ and $n$ divides $ab$ it follows that $36$ divides both $a$ and $b$ . | {
"answer": "1296",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Express $0.3\overline{45}$ as a common fraction. | {
"answer": "\\frac{83}{110}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given 5 points \( A, B, C, D, E \) on a plane, with no three points being collinear. How many different ways can one connect these points with 4 segments such that each point is an endpoint of at least one segment? | {
"answer": "135",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Let $\alpha$ and $\beta$ be acute angles, and $\cos \alpha = \frac{\sqrt{5}}{5}$, $\sin (\alpha + \beta) = \frac{3}{5}$. Find $\cos \beta$. | {
"answer": "\\frac{2\\sqrt{5}}{25}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the following pseudocode:
```
S = 0
i = 1
Do
S = S + i
i = i + 2
Loop while S ≤ 200
n = i - 2
Output n
```
What is the value of the positive integer $n$? | {
"answer": "27",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Six horizontal lines and five vertical lines are drawn in a plane. If a specific point, say (3, 4), exists in the coordinate plane, in how many ways can four lines be chosen such that a rectangular region enclosing the point (3, 4) is formed? | {
"answer": "24",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the parametric equation of circle $C$ as $\begin{cases} x=1+3\cos \theta \\ y=3\sin \theta \end{cases}$ (where $\theta$ is the parameter), and establishing a polar coordinate system with the origin as the pole and the positive half-axis of $x$ as the polar axis, the polar equation of line $l$ is $\theta= \frac {\pi}{4}(\rho\in\mathbb{R})$.
$(1)$ Write the polar coordinates of point $C$ and the polar equation of circle $C$;
$(2)$ Points $A$ and $B$ are respectively on circle $C$ and line $l$, and $\angle ACB= \frac {\pi}{3}$. Find the minimum length of segment $AB$. | {
"answer": "\\frac {3 \\sqrt {3}}{2}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
If 260 were expressed as a sum of at least three distinct powers of 2, what would be the least possible sum of the exponents of these powers? | {
"answer": "10",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Petya plans to spend all 90 days of his vacation in the village, swimming in the lake every second day (i.e., every other day), going shopping for groceries every third day, and solving math problems every fifth day. (On the first day, Petya did all three tasks and got very tired.) How many "pleasant" days will Petya have, when he needs to swim but does not need to go shopping or solve math problems? How many "boring" days will he have, when he has no tasks at all? | {
"answer": "24",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Find the number of positive integers $n$ that satisfy
\[(n - 2)(n - 4)(n - 6) \dotsm (n - 98) < 0.\] | {
"answer": "24",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Consider the parametric equations for a curve given by
\begin{align*}
x &= \cos t + \frac{t}{3}, \\
y &= \sin t.
\end{align*}
Determine how many times the graph intersects itself between $x = 0$ and $x = 60$. | {
"answer": "28",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Points $E$ and $F$ lie inside rectangle $ABCD$ with $AE=DE=BF=CF=EF$ . If $AB=11$ and $BC=8$ , find the area of the quadrilateral $AEFB$ . | {
"answer": "32",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Equilateral $\triangle ABC$ has side length $2$, and shapes $ABDE$, $BCHT$, $CAFG$ are formed outside the triangle such that $ABDE$ and $CAFG$ are squares, and $BCHT$ is an equilateral triangle. What is the area of the geometric shape formed by $DEFGHT$?
A) $3\sqrt{3} - 1$
B) $3\sqrt{3} - 2$
C) $3\sqrt{3} + 2$
D) $4\sqrt{3} - 2$ | {
"answer": "3\\sqrt{3} - 2",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given a magician's hat contains 4 red chips and 2 green chips. Chips are drawn randomly, one at a time without replacement, until all 4 of the reds are drawn or until both green chips are drawn, calculate the probability that all 4 red chips are drawn before both green chips are drawn. | {
"answer": "\\frac{1}{3}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given that the four real roots of the quartic polynomial $f(x)$ form an arithmetic sequence with a common difference of $2$, calculate the difference between the maximum root and the minimum root of $f'(x)$. | {
"answer": "2\\sqrt{5}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
In the diagram, rectangle \(P Q R S\) has \(P Q = 30\) and rectangle \(W X Y Z\) has \(Z Y = 15\). If \(S\) is on \(W X\) and \(X\) is on \(S R\), such that \(S X = 10\), then \(W R\) equals: | {
"answer": "35",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
A right circular cone is inscribed in a right rectangular prism as shown. The base of the prism has dimensions, where one side is exactly twice the length of the other ($a$ and $2a$). The cone's base fits perfectly into the base of the prism making one side of the rectangle the diameter of the cone's base. The height of the prism and the height of the cone are equal. Calculate the ratio of the volume of the cone to the volume of the prism, and express your answer as a common fraction in terms of $\pi$. | {
"answer": "\\frac{\\pi}{24}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
(1) Given a point P(-4, 3) on the terminal side of angle $\alpha$, calculate the value of $$\frac {\cos( \frac {\pi}{2}+\alpha)\sin(-\pi-\alpha)}{\cos( \frac {11\pi}{2}-\alpha )\sin( \frac {9\pi}{2}+\alpha )}$$.
(2) If $\sin x= \frac {m-3}{m+5}$ and $\cos x= \frac {4-2m}{m+5}$, where $x$ is in the interval ($\frac {\pi}{2}$, $\pi$), find $\tan x$. | {
"answer": "-\\frac {5}{12}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given a triangle $ABC$ with $\angle B = \frac{\pi}{3}$,
(I) if $AB=8\sqrt{3}$ and $AC=12$, find the area of $\triangle ABC$;
(II) if $AB=4$ and $\vec{BM} = \vec{MN} = \vec{NC}$ with $AN=2\sqrt{3}BM$, find the length of $AM$. | {
"answer": "\\sqrt{13}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the function $f(x) = 2\sin x \cos x + 2\sqrt{3}\cos^2 x$.
(1) Find the smallest positive period of the function $f(x)$;
(2) When $x \in \left[-\frac{\pi}{3}, \frac{\pi}{3}\right]$, find the maximum and minimum values of the function $f(x)$. | {
"answer": "2 + \\sqrt{3}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given two lines $l_1: y = m$ and $l_2: y = \frac{8}{2m+1}$ ($m > 0$), line $l_1$ intersects the graph of the function $y = |\log_2 x|$ from left to right at points $A$ and $B$, and line $l_2$ intersects the graph of the function $y = |\log_2 x|$ from left to right at points $C$ and $D$. The lengths of the projections of segments $AC$ and $BD$ on the $x$-axis are denoted as $a$ and $b$, respectively. When $m$ varies, the minimum value of $\frac{b}{a}$ is __________. | {
"answer": "8\\sqrt{2}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Find the smallest prime $p$ for which there exist positive integers $a,b$ such that
\[
a^{2} + p^{3} = b^{4}.
\] | {
"answer": "23",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
A pentagonal prism is used as the base of a new pyramid. One of the seven faces of this pentagonal prism will be chosen as the base of the pyramid. Calculate the maximum value of the sum of the exterior faces, vertices, and edges of the resulting structure after this pyramid is added. | {
"answer": "42",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Find the distance between the foci of the ellipse
\[\frac{x^2}{36} + \frac{y^2}{9} = 5.\] | {
"answer": "2\\sqrt{5.4}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the function $f(x)=e^{x}-mx^{3}$ ($m$ is a nonzero constant).
$(1)$ If the function $f(x)$ is increasing on $(0,+\infty)$, find the range of real numbers for $m$.
$(2)$ If $f_{n+1}(x)$ ($n\in \mathbb{N}$) represents the derivative of $f_{n}(x)$, where $f_{0}(x)=f(x)$, and when $m=1$, let $g_{n}(x)=f_{2}(x)+f_{3}(x)+\cdots +f_{n}(x)$ ($n\geqslant 2, n\in \mathbb{N}$). If the minimum value of $y=g_{n}(x)$ is always greater than zero, find the minimum value of $n$. | {
"answer": "n = 8",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Liu and Li, each with one child, go to the park together to play. After buying tickets, they line up to enter the park. For safety reasons, the first and last positions must be occupied by fathers, and the two children must stand together. The number of ways for these 6 people to line up is \_\_\_\_\_\_. | {
"answer": "24",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Twelve tiles numbered $1$ through $12$ are turned face down. One tile is turned up at random, and an 8-sided die is rolled. What is the probability that the product of the numbers on the tile and the die will be a square?
A) $\frac{11}{96}$
B) $\frac{17}{96}$
C) $\frac{21}{96}$
D) $\frac{14}{96}$ | {
"answer": "\\frac{17}{96}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Marisela is putting on a juggling show! She starts with $1$ ball, tossing it once per second. Lawrence tosses her another ball every five seconds, and she always tosses each ball that she has once per second. Compute the total number of tosses Marisela has made one minute after she starts juggling. | {
"answer": "390",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
The area of triangle $\triangle OFA$, where line $l$ has an inclination angle of $60^\circ$ and passes through the focus $F$ of the parabola $y^2=4x$, and intersects with the part of the parabola that lies on the x-axis at point $A$, is equal to $\frac{1}{2}\cdot OA \cdot\frac{1}{2} \cdot OF \cdot \sin \theta$. Determine the value of this expression. | {
"answer": "\\sqrt {3}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Two workers started paving paths in a park simultaneously from point $A$. The first worker paves the section $A-B-C$ and the second worker paves the section $A-D-E-F-C$. They worked at constant speeds and finished at the same time, having spent 9 hours on the job. It is known that the second worker works 1.2 times faster than the first worker. How many minutes did the second worker spend paving the section $DE$? | {
"answer": "45",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
What is the value of $ { \sum_{1 \le i< j \le 10}(i+j)}_{i+j=odd} $ $ - { \sum_{1 \le i< j \le 10}(i+j)}_{i+j=even} $ | {
"answer": "55",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the function $y=ax^{2}+bx+c$, where $a$, $b$, $c\in R$.<br/>$(Ⅰ)$ If $a \gt b \gt c$ and $a+b+c=0$, and the distance between the graph of this function and the $x$-axis is $l$, find the range of values for $l$;<br/>$(Ⅱ)$ If $a \lt b$ and the solution set of the inequality $y \lt 0$ is $\varnothing $, find the minimum value of $\frac{{2a+2b+8c}}{{b-a}}$. | {
"answer": "6+4\\sqrt{3}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
In the diagram, $ABCD$ is a square with side length $8$, and $WXYZ$ is a rectangle with $ZY=12$ and $XY=4$. Additionally, $AD$ and $WX$ are perpendicular. If the shaded area equals three-quarters of the area of $WXYZ$, what is the length of $DP$? | {
"answer": "4.5",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
There are numbers from 1 to 2013 on the blackboard. Each time, two numbers can be erased and replaced with the sum of their digits. This process continues until there are four numbers left, whose product is 27. What is the sum of these four numbers? | {
"answer": "10",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the sets $M={x|m\leqslant x\leqslant m+ \frac {7}{10}}$ and $N={x|n- \frac {2}{5}\leqslant x\leqslant n}$, both of which are subsets of ${x|0\leqslant x\leqslant 1}$, find the minimum value of the "length" of the set $M\cap N$. (Note: The "length" of a set ${x|a\leqslant x\leqslant b}$ is defined as $b-a$.) | {
"answer": "\\frac{1}{10}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
In the Cartesian coordinate plane $(xOy)$, the sum of the distances from point $P$ to the two points $(0,-\sqrt{3})$ and $(0,\sqrt{3})$ is equal to $4$. Let the trajectory of point $P$ be denoted as $C$.
(I) Write the equation of $C$;
(II) If the line $y=kx+1$ intersects $C$ at points $A$ and $B$, for what value of $k$ is $\overrightarrow{OA} \perp \overrightarrow{OB}$? What is the value of $|\overrightarrow{AB}|$ at this time? | {
"answer": "\\frac{4 \\sqrt{65}}{17}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given that \( n! \) is evenly divisible by \( 1 + 2 + \cdots + n \), find the number of positive integers \( n \) less than or equal to 50. | {
"answer": "36",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the parabola $y^2=2px$ ($p>0$) with focus $F(1,0)$, and the line $l: y=x+m$ intersects the parabola at two distinct points $A$ and $B$. If $0\leq m<1$, determine the maximum area of $\triangle FAB$. | {
"answer": "\\frac{8\\sqrt{6}}{9}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the complex number $z$ that satisfies $$z= \frac {1-i}{i}$$ (where $i$ is the imaginary unit), find $z^2$ and $|z|$. | {
"answer": "\\sqrt {2}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
At 7:10 in the morning, Xiao Ming's mother wakes him up and asks him to get up. However, Xiao Ming sees the time in the mirror and thinks that it is not yet time to get up. He tells his mother, "It's still early!" Xiao Ming mistakenly believes that the time is $\qquad$ hours $\qquad$ minutes. | {
"answer": "4:50",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
A monkey in Zoo becomes lucky if he eats three different fruits. What is the largest number of monkeys one can make lucky, by having $20$ oranges, $30$ bananas, $40$ peaches and $50$ tangerines? Justify your answer. | {
"answer": "40",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given a set $I=\{1,2,3,4,5\}$, select two non-empty subsets $A$ and $B$ such that the largest number in set $A$ is less than the smallest number in set $B$. The total number of different selection methods is $\_\_\_\_\_\_$. | {
"answer": "49",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given an arithmetic sequence ${a_{n}}$, let $S_{n}$ denote the sum of its first $n$ terms. The first term $a_{1}$ is given as $-20$. The common difference is a real number in the interval $(3,5)$. Determine the probability that the minimum value of $S_{n}$ is only $S_{6}$. | {
"answer": "\\dfrac{1}{3}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Let $ f (n) $ be a function that fulfills the following properties: $\bullet$ For each natural $ n $ , $ f (n) $ is an integer greater than or equal to $ 0 $ . $\bullet$ $f (n) = 2010 $ , if $ n $ ends in $ 7 $ . For example, $ f (137) = 2010 $ . $\bullet$ If $ a $ is a divisor of $ b $ , then: $ f \left(\frac {b} {a} \right) = | f (b) -f (a) | $ .
Find $ \displaystyle f (2009 ^ {2009 ^ {2009}}) $ and justify your answer. | {
"answer": "2010",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
A store is having a sale for a change of season, offering discounts on a certain type of clothing. If each item is sold at 40% of the marked price, there is a loss of 30 yuan per item, while selling it at 70% of the marked price yields a profit of 60 yuan per item.
Find:
(1) What is the marked price of each item of clothing?
(2) To ensure no loss is incurred, what is the maximum discount that can be offered on this clothing? | {
"answer": "50\\%",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
On a road of length $A B = 8 \text{ km}$, buses travel in both directions at a speed of $12 \text{ km/h}$. The first bus from each location starts at 6 o'clock, with subsequent buses departing every 10 minutes.
A pedestrian starts walking from $A$ to $B$ at $\frac{81}{4}$ hours; their speed is $4 \text{ km/h}$.
Determine graphically how many oncoming buses the pedestrian will meet, and also when and where these encounters will happen. | {
"answer": "16",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
On a sphere, there are four points A, B, C, and D satisfying $AB=1$, $BC=\sqrt{3}$, $AC=2$. If the maximum volume of tetrahedron D-ABC is $\frac{\sqrt{3}}{2}$, then the surface area of this sphere is _______. | {
"answer": "\\frac{100\\pi}{9}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
In a modified game, each of 5 players rolls a standard 6-sided die. The winner is the player who rolls the highest number. If there is a tie for the highest roll, those involved must roll again. This continues until only one person has the highest number. If Cecilia is one of the players, what is the probability that Cecilia's first roll was a 4, given that she won the game?
A) $\frac{41}{144}$
B) $\frac{256}{1555}$
C) $\frac{128}{1296}$
D) $\frac{61}{216}$ | {
"answer": "\\frac{256}{1555}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
For real numbers $a,$ $b,$ and $c,$ and a real scalar $\lambda,$ consider the matrix
\[\begin{pmatrix} a + \lambda & b & c \\ b & c + \lambda & a \\ c & a & b + \lambda \end{pmatrix}.\] Determine all possible values of \[\frac{a}{b + c} + \frac{b}{a + c} + \frac{c}{a + b}\] assuming the matrix is not invertible. | {
"answer": "\\frac{3}{2}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
Given the coordinates of the three vertices of $\triangle P_{1}P_{2}P_{3}$ are $P_{1}(1,2)$, $P_{2}(4,3)$, and $P_{3}(3,-1)$, the length of the longest edge is ________, and the length of the shortest edge is ________. | {
"answer": "\\sqrt {10}",
"ground_truth": null,
"style": null,
"task_type": "math"
} |
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