Answer: C

Solution:

We can simplify the expression as follows: $$\begin{align*} \dfrac{(2112 - 2021)^2}{169} &= \dfrac{91^2}{169} \\ &= \dfrac{91^2}{13^2} \\ &= \left(\dfrac{91}{13}\right)^2 \\ &= 7^2 \\ &= 49. \end{align*}$$

Thus, C is the correct answer.

Answer: E

Solution:

If she shortens the $4$ unit side by $1,$ she has a $3 \times 6$ card, which has an area of $2 \cdot 6 = 18.$

If Menkara shortens the other side, she gets a $4 \cdot 5$ card, which has an area of $4 \cdot 5 = 20.$

In the problem, Menkara shortened the $4$ unit side. Therefore, the area of the card if she shortened the other side is $20.$

Thus, E is the correct answer.

Answer: D

Solution:

The volume of the cube is $6^3 = 216.$ The volume of a ball of clay is $\dfrac{4}{3} \pi 2^3 = \dfrac{32 \pi}{3}.$

Since the balls can be reshaped but not compressed, the answer is $$\left \lfloor \dfrac{216}{\dfrac{32 \pi}{3}} \right \rfloor = \left \lfloor \dfrac{81 \pi}{4} \right \rfloor.$$

Approximating using $\pi \approx 3.14,$ we get $$12 \leq 4 \pi \leq 13$$ and $$\left \lfloor \dfrac{81}{13} \right \rfloor \leq \left \lfloor \dfrac{81}{4 \pi} \right \rfloor \leq \left \lfloor \dfrac{81}{12} \right \rfloor.$$ Since $$\left \lfloor \dfrac{81}{12} \right \rfloor = \left \lfloor \dfrac{81}{12} \right \rfloor = 6,$$ we get that $$\left \lfloor \dfrac{81}{4 \pi} \right \rfloor = 6.$$

Thus, D is the correct answer.

Answer: B

Solution:

Mr. Lopez would take $$\dfrac{6}{30} \cdot 60 = 12$$ minutes to travel on Route A.

On Route B, he would take $$\left(\dfrac{5 - .5}{40} + \dfrac{.5}{20}\right) \cdot 60 = 8.25$$ minutes.

The difference in times along these routes is $12 - 8.25 = 3.75$ minutes.

Thus, B is the correct answer.

Answer: E

Solution:

Note that $A$ cannot be even, as then the number would be divisible by $2.$

$A$ also cannot be $5,$ as that would make the number divisible by $5.$

If $A$ equaled $1$ or $7,$ then the sum of the digits of the number would be $6$ and $12$ respectively.

This would make the number divisible by $3,$ so that rules out $A$ equaling either of these numbers.

Finally, if $A$ equals $3,$ then the whole number becomes $202109.$ If we look at the difference of the sums of alternating digits, we get $$2 + 2 - 1 - 3 = 0,$$ which means the number is divisible by $11.$

This means that $A$ must be $9.$

Thus, E is the correct answer.

Answer: B

Solution:

There are $40$ gaps between the $1$ st and $41$ st pole, which means that the distance between consecutive poles is $$5280 \div 40 = 132$$ feet.

This means that each of Elmer's strides is $$132 \div 44 = 3$$ feet. Similarly, each of Oscar's strides is $$132 \div 12 = 11$$ feet. This makes Oscar's leap $11 - 3 = 8$ feet longer.

Thus, B is the correct answer.

Answer: D

Solution:

Since $\angle ADC = 90^{\circ},$ we get that $$\angle FDE = 360^{\circ} - 90^{\circ} - 110^{\circ}$$$$= 160^{\circ}.$$ Also since $\triangle FDE$ is isosceles, we get that $$\angle EFD = \dfrac{180^{\circ} - 160^{\circ}}{2} = 10^{\circ}.$$ Finally, we get that $$\angle AFE = 180^{\circ} - 10^{\circ} = 170^{\circ}.$$

Thus, D is the correct answer.

Answer: B

Solution:

Let $\underline{a} \ \underline{b}$ be a $2$-digit cuddly number.

Then $$10a + b = a + b^2.$$ Rearranging, we get $$9a = b(b - 1).$$ This means that $9$ divides either $b$ or $b - 1$ ($3$ cannot divide both $b$ and $b - 1$).

The only way this is possible is if $b = 9$ ($b$ is one digit, so it can't be anything else). Checking, we get that $89$ is a cuddly number. This shows that there is only $1$ two-digit cuddly number.

Thus, B is the correct answer.

Answer: E

Solution:

Let $p$ be the probability that an odd number is rolled. Then $3p$ is the probability an even number is rolled. We know that $$p + 3p = 1 \Rightarrow p = \dfrac{1}{4}.$$

The only way for the sum to be even is if both rolls have the same parity. This happens with a probability of $$\dfrac{1}{4}^2 + \dfrac{3}{4}^2 = \dfrac{10}{16} = \dfrac{5}{8}.$$

Thus, E is the correct answer.

Answer: B

Solution:

Recall $$\text{Expected value} =$$$$\Sigma (\text{Outcome} \cdot \text{Probability}).$$

Therefore, $$t = \dfrac{1}{5} (50 + 20 + 20 + 5 + 5)$$ $$= \dfrac{1}{5} \cdot 100 = 20$$ and $$s = 50 \cdot \dfrac{50}{100} + 20 \cdot \dfrac{20}{100}$$$$+ 20 \cdot \dfrac{20}{100} + 5 \cdot \dfrac{5}{100} + 5 \cdot \dfrac{5}{100}$$ $$= 25 + 4 + 4 + .25 + .25 = 33.5$$

$t - s = -13.5.$

Thus, B is the correct answer.

Answer: A

Solution:

Let $x$ be the length of the ship. Then in the time that Emily moves $210$ steps, the ship moves $210 - x$ steps.

In the time that Emily moves $42$ steps, the ship moves $x - 42$ steps. Since the ship and Emily move at a constant rate $$\dfrac{210}{210 - x} = \dfrac{42}{x - 42}.$$ Cross-multiplying yields $$210x - 210 \cdot 42 = 210 \cdot 42 - 42x$$ $$42 \cdot 6 x = 2 \cdot 42 \cdot 210$$ $$x = 70.$$

Thus, A is the correct answer.

Answer: D

Solution:

Note that $$9 \equiv -1 \pmod{5}.$$ Then if expand $N$ using the definition of bases, we get $$N = 2 \cdot 9^{10} + 7 \cdot 9^9 + 6 \cdot 9^6 +$$$$5 \cdot 9 + 2$$ $$\equiv 2 (-1)^{10} + 7 (-1)^9 + 6 (-1)^6 +$$$$5 (-1) + 2 \pmod{5}$$ $$\equiv 2 - 7 + 6 - 5 + 2 \pmod{5}$$ $$\equiv 3 \pmod{5}.$$

Thus, D is the correct answer.

Answer: D

Solution:

Note that for this restriction to hold, there must be $3$ balls of each color.

There are $2^6 = 64$ ways to color the balls and $\binom{6}{3} = 20$ to choose which balls are white.

The desired probability is therefore $\dfrac{20}{64} = \dfrac{5}{16}.$

Thus, D is the correct answer.

Answer: D

Solution:

The second equation seems very similar to that of a diamond. Rearranging, we get $$|x| + |y| - 4 = \pm 1$$$$|x| + |y| = \{3, 5\}.$$

We can graph this to see if we can figure out where the intersection points are.

From this, we can see that there are $5$ intersection points.

Thus, D is the correct answer.

Answer: C

Solution:

Let $\odot C_1$ be the circle that is tangent to $AB$ and $AC.$ Then $$\angle ABO_1 = \angle ACO_1 = 90^{\circ},$$ making the two angles supplementary. This makes $ABO_1C$ cyclic.

Let $\odot O_2$ be the circumcircle of $ABO_1C.$ This makes $\odot O_2$ the circumcircle of $\triangle ABC$ as well.

We also know that $AO_1$ is the diameter of $O_2$ since $AO_1$ bisects $\angle BAC.$

By the Pythagorean theorem, we get that $$\begin{align*} AO_1 &= \sqrt{AB^2 + BO_1^2} \\ &= \sqrt{54 + 50} \\ &= 2\sqrt{26}. \end{align*}$$ This makes the area of $\odot O_2$ $26 \pi.$

Thus, C is the correct answer.

Answer: D

Solution:

Note that $$f(1 - x) = \mid \lfloor 1 - x \rfloor \mid - \mid \lfloor x \rfloor \mid$$$$= -f(x).$$

This means that $$f(\dfrac{1}{2} + x) = -f(\dfrac{1}{2} - x).$$

Therefore, the graph is symmetric about the point $(\dfrac{1}{2}, 0).$

Thus, D is the correct answer.

Answer: D

Solution:

Note that the inclination from pillar $A$ to pillar $B$ is $3$ since the solar panel is flat.

Let $G$ be the center of the solar panel. Since $\overline{CG} \mid \mid \overline{BA},$ we get that the height at $G$ is $10 + 3 = 13.$

We also know that the heights at $B, G,$ and $E$ are collinear. This makes the height of the pillar at $E$ $$9 + 4 + 4 = 17.$$

Thus, D is the correct answer.

Answer: C

Solution:

There are $2$ cases.

Case $1:$ the top-right and bottom-left sections have the same crop

There are $4$ options for which crop is in those sections. The other two sections have $3$ options for the crop since each crop has one restriction for crops next to it. This gives us $$4 \cdot 3 \cdot 3 = 36$$ combinations.

Case $2:$ the top-right and bottom-left sections have different crops

There are $4$ options for which crop is in the top-left section. Then there are $3$ options for the top-right and $2$ for the bottom-left. This leaves $2$ options for the bottom-right section. This gives us another $$4 \cdot 3 \cdot 2 \cdot 2 = 48$$ configurations.

In total, there are $36 + 48 = 84$ combinations.

Thus, C is the correct answer.

Answer: A

Solution:

The side length of the inner square traced out by the inner circle is $s - 4.$

There are also the small pieces remaining in the corner. These form a total area of $$(1 + 1)^2 - \pi 1^2 = 4 - \pi.$$

Therefore, $$A = s^2 - (s - 4)^2 - (4 - \pi)$$$$= 8s - 20 + \pi.$$

The outer disk traces out an area that is comprised of $4$ rectangles and $4$ quarter-circles. The rectangles have area $s \cdot 2 = 2s$ and the quarter-circles form a circle with radius $2$ and area $4 \pi.$

This gives us $$2A = 8s + 4 \pi.$$

Equating the two equations we get $$8s + 4 \pi = 2(8s - 20 + \pi).$$ Solving yields $$8s = 40 + 2 \pi$$$$s = 5 + \dfrac{\pi}{4}.$$

Thus, A is the correct answer.

Answer: B

Solution:

Recall that the only way a quadratic does not have distinct, real solutions is if the discriminant is nonpositive.

This gives us that $$b^2 \leq 4c \text{ and } c^2 \leq 4b.$$

Squaring the first inequality gives us that $b^4 \leq 16c^2$ since $b$ and $c$ are positive.

Multiplying the second inequality by $16$ and combining gives us $$b^4 \leq 16c^2 \leq 64b.$$

The only values of $b$ that satisfy $b^4 \leq 64b$ are $1, 2, 3,$ and $4.$

Case $1: b = 1$

This gives us $$1 \leq 16c^2 \leq 64.$$

Only $c = 1$ and $c = 2$ work.

Case $2: b = 2$

This gives us $$16 \leq 16c^2 \leq 128.$$

Only $c = 1$ and $c = 2$ work.

Case $3: b = 3$

This gives us $$81 \leq 16c^2 \leq 192.$$

Only $c = 3$ works.

Case $4: b = 4$

This gives us $$256 \leq 16c^2 \leq 256.$$

Only $c = 1$ works.

This gives us a total of $6$ pairs that work.

Thus, B is the correct answer.

Answer: E

Solution:

For the sake of simplicity, we can assume the balls and bins are both distinguishable.

Since each case includes having $4$ balls in $3$ bins, we can leave those out during our calculation.

For $p,$ there are $5$ choices for the bin with $3$ balls and then $4$ choices for the bin with $5$ balls. Finally, there are $\binom{8}{3} = 56$ ways to choose which balls go in the bins.

For $q,$ after cancelling out $3$ of the $4$ s, there are $\binom{8}{4} = 70$ ways to ensure $4$ balls go in each of the remaining bins.

Since the total number of distributions is the same for both $p$ and $q,$ we can let $\dfrac{p}{q}$ be the ratio of the numerators. Therefore, $$\dfrac{p}{q} = \dfrac{20 \cdot 56}{70} = 16.$$

Thus, E is the correct answer.

Answer: B

Solution:

We can use coordinate geometry to solve this problem.

WLOG, let the origin be the center of the base of the cone. Then let the center of the one of the spheres be $(0, \dfrac{2r}{\sqrt{3}}, r).$ We get this $y$-coordinate since the centers of the spheres form an equilateral triangle.

We know that this sphere is internally tangent to the cone, so we know that it is tangent to the plane with equation $$5x + 12y = 60.$$ The distance from the center of the sphere to this plane is then $r.$

Using the formula for the distance to a plane from a point, we get $$r = \dfrac{\left \lvert 12 \cdot \dfrac{2r}{\sqrt{3}} + 5r - 60 \right \rvert}{\sqrt{0^2 + 5^2 + 12^2}}.$$

Solving for $r,$ we get $$r = \dfrac{\mid (5 + 8\sqrt{3})r - 60 \mid}{13}$$ $$13r = -(5 + 8\sqrt{3})r + 60$$ $$(8\sqrt{3} + 18)r = 60$$ $$r = \dfrac{30}{4\sqrt{3} + 9} \cdot \dfrac{9 - 4\sqrt{3}}{9 - 4\sqrt{3}}$$ $$r = \dfrac{30(9 - 4\sqrt{3})}{33}$$ $$r = \dfrac{90 - 40\sqrt{3}}{11}.$$

Thus, B is the correct answer.

Answer: D

Solution:

First, let us see what values of $x$ satisfy $f_1(x) = 12.$ For this to happen, $x$ must have $6$ factors. This is only possible if $x = pq^2$ or $x = p^5$ where $p$ and $q$ are primes.

The only numbers less than $50$ that work are $$12, 18, 20, 28, 44, 45, \text{ and } 50.$$

Note that $f_1(12) = 12.$ This means that if $f_i(x) = 12,$ then $f_n(x) = 12$ when $n \geq i.$

This means that all the values listed above satisfy $f_{50}(x) = 12.$ This also tells us that if some $f_i(x)$ equals any of the above numbers, then $f_{50}(x) = 12.$

The only possibilities such that $x \leq 50$ is if $f_1(x)$ is either $18$ or $20.$ This means $x$ must have either $9$ or $10$ factors.

This means $x$ is of the form $p^2q^2$ or $p^4q.$ The only numbers less than $50$ that work are $36$ and $48.$

We have exhausted all the possible values $n$ such that $f_{50}(n) = 12.$ This gives us $10$ total solutions.

Thus, D is the correct answer.

Answer: E

Solution:

Label the cube as follows.

Note that each face must have $2$ zeros and $2$ ones.This means that for all $6$ faces, there are $6$ zeros and $6$ ones.

We can case on the sides of $ABCD.$

Case $1:$ opposite sides have the same label

This gives us $2$ ways to label the edges of $ABCD.$ WLOG, let $\overline{AB}, \overline{BC}, \overline{CD},$ and $\overline{DA}$ be labeled $1, 0, 1, 0$ respectively. We multiply by $2$ at the end to take care of the other case.

Then we can apply casework to the label of $\overline{AE}.$

If its label is $1,$ then we know that the label of $\overline{EF}$ and $\overline{BF}$ is $0$ to satisfy the condition for the top face.

Then $\overline{FG}$ and $\overline{CG}$ must be $1.$ This forces $\overline{DH}$ and $\overline{GH}$ to be $0.$ Finally, $\overline{EH}$ must be $0.$

If $\overline{AE}$ is $0,$ we can walk through all the faces as before, which will tell us that there is only $1$ possible case in this scenario.

Therefore, this cases has $2 \cdot 2 = 4$ possible labelings.

Case $2:$ opposite edges have different labels

There are $4$ ways to label the faces of $ABCD.$ WLOG, label $\overline{AB}, \overline{BC}, \overline{CD},$ and $\overline{DA}$ be labeled $1, 1, 0, 0$ respectively. We can multiply by $4$ at the end for the other cases.

Now we case on the labels of $\overline{AE}$ and $\overline{BF}.$

As above, we can go through each pair of labels to see that each pair only gives us one possible labeling of the cube. There are $4$ pairs, so this gives us $4$ configurations.

Therefore, this case has $4 \cdot 4 = 16$ possible labelings.

Finally, there are a total of $4 + 16 = 20$ labelings.

Thus, E is the correct answer.

Answer: A

Solution:

Let $r$ and $s$ be the roots of $\tilde{p}(x).$ Then $$\tilde{p}(x) = (x - r)(x - s)$$$$= x^2 - (r + s) + rs.$$

Note that the solutions to $\tilde{p}(\tilde{p}(x)) = 0$ are the solutions to $$\tilde{p}(x) - r =$$$$x^2 - (r + s)x + (rs - r) = 0$$ and $$\begin{gather*} \tilde{p}(x) - s = \\ x^2 - (r + s)x + (rs - s) = 0. \end{gather*}$$

Since there are only $3$ distinct solutions, one of these quadratics must have a double root, and the other has to have $2$ distinct roots.

WLOG, let the first equation be the one with a double root. Then we know that its discriminant is $0.$ This give us $$\begin{gather*} (r + s)^2 = 4rs - 4r \\ r - s = \pm 2 \sqrt{-r}. \end{gather*}$$

For the other equation to have $2$ solutions, its discriminant must be positive. $$\begin{gather*} (r + s)^2 - 4rs + 4s \gt 0 \\ (r - s)^2 \gt -4s \\ -4r \gt -4s \\ r - s \lt 0 \end{gather*}$$

From above, we can conclude that $r - s = -2\sqrt{r}.$

We know that the sum of the roots of $\tilde{p}(x)$ is $$r + s = 2r + 2\sqrt{-r}.$$ This is maximized when $r = -\dfrac{1}{4},$ yielding $s = \dfrac{3}{4}.$ Then $$\tilde{p}(1) = 1^2 - \dfrac{1}{2} \cdot 1 - \dfrac{3}{16} = \dfrac{5}{16}.$$

Thus, A is the correct answer.