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Difference between revisions of "2015 AMC 12B Problems/Problem 25"

(Condensed Solution like That of Solution 2: Clarified)
(Solution 5 (big complex bash))
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Multiplying out, we have <math>1008\sqrt{2}+1008\sqrt{6}</math>, so the answer is <math>1008+2+1008+6= \boxed {\bold {(B)}\; 2024}</math>.
 
Multiplying out, we have <math>1008\sqrt{2}+1008\sqrt{6}</math>, so the answer is <math>1008+2+1008+6= \boxed {\bold {(B)}\; 2024}</math>.
  
==Condensed Solution like That of Solution 2==
+
==Solution 3==
BEST NOT TO USE LINED PAPER!
+
We first notice that if the bee is turning 30 degrees each turn, it will take 12 turns to be looking in the same direction when the bee initially left. This means we simply need to answer the question; how far will the bee be when the bee is facing in the same direction?
  
Fundamental notes: Every 12 turns the bee is oriented at the same angle, and 2015 is <math>11 (\mod 12)</math>.
 
  
We solve by looking at the final abscissa and ordinate. Disregard ones with a cosine or sine of zero; they don't matter.
+
First we use the fact that after 3 turns, the bee will be facing in a direction perpendicular to the the initial direction. From here we can draw a perpendicular from <math>P_2</math> to the line <math>\overline{P_0P_1}</math> intersecting a point <math>C_0</math>. We will also place the point <math>C_1</math> at the intersection of <math>\overline{P_0P_1}</math> and <math>\overline{P_3P_4}</math>. In addition, the point <math>C_2</math> is placed at the perpendicular dropped from <math>P_2</math> to the line <math>\overline{P_3C_1}</math>. We will also set the distance <math>\overline{P_0P_1} = n</math> and thus <math>\overline{P_1P_2} = n+1</math>. With this perpendicular we see that the triangle <math>\triangle{P_1P_2C_0}</math> is a 30-60-90 triangle. This means that the length <math>\overline{P_1C_0} = \frac{(n+1)\sqrt{3}}{2}</math> and the length <math>\overline{C_1C_2} = \frac{n+1}{2}</math>. We can also see that the triangle <math>\triangle{P_2C_1P_3}</math> is a 30-60-90 triangle and thus <math>\overline{C_0C_1} = \frac{n+2}{2}</math> and <math>\overline{C_2P_3} = \frac{(n+2)\sqrt{3}}{2}</math>. Now if we continue this across all <math>P_i</math> and set the point <math>P_0</math> to the coordinates <math>(0, 0)</math>. As you can see, we are inherently putting a “box” around the figure. Doing similar calculations for all four “sides” of this spiral we get that the length
  
ABSCISSA: Notice that the change in the abscissa is, upon each move, <math>j \cos(theta)</math>. Therefore we are looking for the sum of:
+
<cmath>\overline{P_0C_1} = n + \frac{(n+1)\sqrt{3}}{2} + \frac{n+2}{2}</cmath><cmath>\overline{C_1C_4} = \frac{(n+1)}{2} + \frac{(n+2)\sqrt{3}}{2} + (n+3) + \frac{(n+4)\sqrt{3}}{2} + \frac{n+5}{2}</cmath>, <cmath>\overline{C_4C_7} = \frac{(n+4)}{2} + \frac{(n+5)\sqrt{3}}{2} + (n+6) + \frac{(n+7)\sqrt{3}}{2} + \frac{n+8}{2}</cmath>, <cmath>\overline{C_7C_{10}} = \frac{(n+7)}{2} + \frac{(n+8)\sqrt{3}}{2} + (n+9) + \frac{(n+10)\sqrt{3}}{2} + \frac{n+11}{2}</cmath>, and finally <cmath>\overline{C_{10}P_{12}} = \frac{(n+10)}{2} + \frac{(n+11)\sqrt{3}}{2}</cmath>.  
<math>1 * (1+...+2005)</math>, <math>\frac{\sqrt{3}}{2} * (2+...+2006)</math> and so on (of course, write them down). The last summation contains numbers <math>12+..+2004</math> instead of 2016. Also note that there are 168 terms for each sequence except the last one.
 
  
Compare the cosine values with absolute value 1. Because each term with <math>+1</math> is 6 less than each term with a cosine value of <math>-1</math>, you get <math>-6*168=-1008</math>.  
+
Here the point <math>C_4</math> is defined as the intersection of lines <math>\overline{P_3P_4}</math> and <math>\overline{P_6P_7}</math>. The point <math>C_7</math> is defined as the intersection of lines <math>\overline{P_6P_7}</math> and <math>\overline{P_9P_{10}}</math>. Finally, the point <math>C_10</math> is defined as the intersection of lines <math>\overline{P_{9}P_{10}}</math> and <math>\overline{P_{12}P_{13}}</math>. Note that our spiral stops at <math>P_{12}</math> before the next spiral starts. Calculating the offset from the x and the y direction, we see that the offset, or the new point <math>P_{12}</math>, is <math>({-6}, {-6}-12 \sqrt{3})</math>. This is an interesting property that the points’ coordinate changes by a constant offset no matter what <math>n</math> is. Since the new point’s subscript changes by 12 each time and we see that 2016 is divisible by 12, the point <math>P_{2016} = ({-168} \cdot {6}, {168} \cdot ({-6} \sqrt{3} {-12}))</math>. Using similar 30-60-90 triangle properties, we see that <math>P_{2015} = ({-6} \cdot 168-1008 \sqrt{3}, 168({-6} \sqrt{3} - 12) + 1008)</math>. Using the distance formula, the numbers cancel out nicely (1008 is divisible by 168, so take 168 when using the distance formula) and we see that the final answer is <math>(1008)(1+\sqrt{3})(\sqrt{2})</math> which gives us a final answer of <math>\boxed{2024}</math>.
  
Note that all the numbers with a <math>cos</math> of absolute value of +-0.5 cancel out by symmetry.
+
-bowmanrocks32
 
 
Finally, on to the square-root terms- there are 4 of these cosine values total. Cases are symmetric, except the second <math>+\frac{\sqrt{3}}{2}</math> lacks the <math>2016</math> which would have given a sum of zero. Therefore, we have to subtract <math>1008\sqrt{3}</math>. So the abscissa is <math>-1008-1008\sqrt{3}</math>.
 
 
 
ORDINATE: This case is just like the one discussed before- and write out all sums like shown above.
 
 
 
For the 2 sine values with absolute value 1 and their sequence, we need to subtract <math>6*168=1008</math> because each term in <math>1(4+...+2008)</math> is 6 less than those in <math>-1(10+...+2014)</math>.
 
 
 
The case of the 4 sine values with absolute value <math>\frac{1}{2}</math>: Pair up the <math>\frac{1}{2}(2+...+2006)</math> with <math>-\frac{1}{2}(8+....+2012)</math> and likewise for <math>\frac{1}{2}(4+...+2008)</math> with <math>-\frac{1}{2}(10+...+2004)</math>, and we should subtract (6 difference in magnitude) * (2 of these scenarios) * (168 terms per each) * (sine value of 0.5) = 1008, but don't forget that we have to add back a 2016 * <math>\frac{1}{2}</math>=1008 because there is no 2016 term! Therefore, there is NO net addition for this case.
 
  
Now for the square-root ones, each term can be paired up with a negative term that has a greater magnitude by 6, meaning <math>(6+6)*168*\sqrt{3}*\frac{1}{2}=-1008\sqrt{3}</math>. Note that there are TWO such pairs, each with this 6-magnitude difference, which is why we have <math>(6+6)</math>, and that there are <math>168</math> terms for each series.
 
  
Since the abscissa and ordinate are equal, the distance is just <math>\sqrt{2}</math> times their magnitude. By the requirements of the problem, our answer is <math>1008+1008+2+6=2024 \boxed{(B)}</math>!
+
==Solution 4==
 +
Suppose that the bee makes a move of distance <math>i</math>. After 6 turns it will be facing the opposite direction and move <math>i+6</math> units. Combining these opposite movements gives a total movement of <math>-6</math> units. The bee makes a total of <math>2016=12\cdot 168</math> moves, so there are <math>168</math> of these pairs, for each direction the bee faces (<math>0^\circ, 30^\circ, 60^\circ, 90^\circ, 120^\circ, 150^\circ</math>). To keep the numbers small, we will multiply by <math>6\cdot 168=1008</math> at the end.
  
==Solution 3==
+
We draw a quick diagram of one unit in each direction.
We first notice that if the bee is turning 30 degrees each turn, it will take 12 turns to be looking in the same direction when the bee initially left. This means we simply need to answer the question; how far will the bee be when the bee is facing in the same direction?
+
<asy>
 +
draw((0,0)--(1,0)--(1+sqrt(3)/2, 1/2)--(3/2+sqrt(3)/2, 1/2+sqrt(3)/2)--(3/2+sqrt(3)/2, 3/2+sqrt(3)/2)--(1+sqrt(3)/2, 3/2+sqrt(3))--(1, 2+sqrt(3)));
 +
draw((1,0)--(3/2+sqrt(3)/2, 0), dashed);
 +
draw((1,2+sqrt(3))--(3/2+sqrt(3)/2, 2+sqrt(3)), dashed);
 +
draw((3/2+sqrt(3)/2, 2+sqrt(3))--(3/2+sqrt(3)/2, 0), dashed);
 +
draw((1+sqrt(3)/2,0)--(1+sqrt(3)/2, 1/2)--(3/2+sqrt(3)/2, 1/2), dashed);
 +
draw((1+sqrt(3)/2,2+sqrt(3))--(1+sqrt(3)/2, 3/2+sqrt(3))--(3/2+sqrt(3)/2, 3/2+sqrt(3)), dashed);
 +
</asy>
 +
Using the 30-60-90 triangles, it is clear that the displacement vector is <math>\langle 1, 2+\sqrt{3}\rangle</math>, or the displacement length is <math>\sqrt{1^2+(2+\sqrt{3})^2}=\sqrt{8+4\sqrt{3}}=\sqrt{2}+\sqrt{6}</math>. Therefore the total displacement is <math>\left|-1008\left(\sqrt{2}+\sqrt{6}\right)\right|= 1008\sqrt{2}+1008\sqrt{6}\implies 1008+2+1008+6=\boxed{\text{(B) }2024}</math>
  
 +
==Solution 5 (big complex bash)==
 +
Let <math>P_0</math> be the origin. East would be the real axis in the positive direction. Then we can assign each <math>P_n</math> a complex value. The displacement would then be the magnitude of the complex number.
  
First we use the fact that after 3 turns, the bee will be facing in a direction perpendicular to the the initial direction. From here we can draw a perpendicular from <math>P_2</math> to the line <math>\overline{P_0P_1}</math> intersecting a point <math>C_0</math>. We will also place the point <math>C_1</math> at the intersection of <math>\overline{P_0P_1}</math> and <math>\overline{P_3P_4}</math>. In addition, the point <math>C_2</math> is placed at the perpendicular dropped from <math>P_2</math> to the line <math>\overline{P_3C_1}</math>. We will also set the distance <math>\overline{P_0P_1} = n</math> and thus <math>\overline{P_1P_2} = n+1</math>. With this perpendicular we see that the triangle <math>\triangle{P_1P_2C_0}</math> is a 30-60-90 triangle. This means that the length <math>\overline{P_1C_0} = \frac{(n+1)\sqrt{3}}{2}</math> and the length <math>\overline{C_1C_2} = \frac{n+1}{2}</math>. We can also see that the triangle <math>\triangle{P_2C_1P_3}</math> is a 30-60-90 triangle and thus <math>\overline{C_0C_1} = \frac{n+2}{2}</math> and <math>\overline{C_2P_3} = \frac{(n+2)\sqrt{3}}{2}</math>. Now if we continue this across all <math>P_i</math> and set the point <math>P_0</math> to the coordinates <math>(0, 0)</math>. As you can see, we are inherently putting a “box” around the figure. Doing similar calculations for all four “sides” of this spiral we get that the length
+
Notice that after the <math>n</math>th move the value of <math>P_n</math> is <math>P_{n-1}+ne^{\frac{i(n-1)\pi}{6}}</math>. Also notice that after six moves the bee is facing in the opposite direction. And because we have found a recursion, we can add these up.  
  
<cmath>\overline{P_0C_1} = n + \frac{(n+1)\sqrt{3}}{2} + \frac{n+2}{2}</cmath>,  <cmath>\overline{C_1C_4} = \frac{(n+1)}{2} + \frac{(n+2)\sqrt{3}}{2} + (n+3) + \frac{(n+4)\sqrt{3}}{2} + \frac{n+5}{2}</cmath>, <cmath>\overline{C_4C_7} = \frac{(n+4)}{2} + \frac{(n+5)\sqrt{3}}{2} + (n+6) + \frac{(n+7)\sqrt{3}}{2} + \frac{n+8}{2}</cmath>, <cmath>\overline{C_7C_{10}} = \frac{(n+7)}{2} + \frac{(n+8)\sqrt{3}}{2} + (n+9) + \frac{(n+10)\sqrt{3}}{2} + \frac{n+11}{2}</cmath>, and finally <cmath>\overline{C_{10}P_{12}} = \frac{(n+10)}{2} + \frac{(n+11)\sqrt{3}}{2}</cmath>.
+
Then we have <cmath>P_n=e^{0}+2e^{\frac{i\pi}{6}}+\cdots+2015e^{\frac{2014i\pi}{6}},</cmath> and this becomes <cmath>(1-7+13-\cdots-2011)e^0+(2-8+\cdots-2012)e^{\frac{i\pi}{6}}+\cdots+(6-12+\cdots+2010)e^{\frac{5i\pi}{6}}.</cmath>
  
Here the point <math>C_4</math> is defined as the intersection of lines <math>\overline{P_3P_4}</math> and <math>\overline{P_6P_7}</math>. The point <math>C_7</math> is defined as the intersection of lines <math>\overline{P_6P_7}</math> and <math>\overline{P_9P_{10}}</math>. Finally, the point <math>C_10</math> is defined as the intersection of lines <math>\overline{P_{9}P_{10}}</math> and <math>\overline{P_{12}P_{13}}</math>. Note that our spiral stops at <math>P_{12}</math> before the next spiral starts. Calculating the offset from the x and the y direction, we see that the offset, or the new point <math>P_{12}</math>, is <math>({-6}, {-6}-12 \sqrt{3})</math>. This is an interesting property that the points’ coordinate changes by a constant offset no matter what <math>n</math> is. Since the new point’s subscript changes by 12 each time and we see that 2016 is divisible by 12, the point <math>P_{2016} = ({-168} \cdot {6}, {168} \cdot ({-6} \sqrt{3} {-12}))</math>. Using similar 30-60-90 triangle properties, we see that <math>P_{2015} = ({-6} \cdot 168-1008 \sqrt{3}, 168({-6} \sqrt{3} - 12) + 1008)</math>. Using the distance formula, the numbers cancel out nicely (1008 is divisible by 168, so take 168 when using the distance formula) and we see that the final answer is <math>(1008)(1+\sqrt{3})(\sqrt{2})</math> which gives us a final answer of <math>\boxed{2024}</math>.
+
Simplifying, we have <cmath>-6\cdot168-6\cdot168e^{\frac{i\pi}{6}}-6\cdot168e^{\frac{2i\pi}{6}}-6\cdot168e^{\frac{3i\pi}{6}}-6\cdot168e^{\frac{4i\pi}{6}}-(2010-6\cdot167)e^{\frac{5i\pi}{6}},</cmath> which eventually simplifies to <cmath>-1008-(2+\sqrt3)1008i,</cmath> and this is a <math>15-75-90</math> triangle which has ratios of <math>1:(2+\sqrt3):(\sqrt2+\sqrt6)</math> so the magnitude is <math>1008\sqrt2+1008\sqrt6</math> and the answer is <math>1008+2+1008+6=\boxed{\text{(B) }2024}</math>.
  
-bowmanrocks32
+
~caroline2023
  
 
==See Also==
 
==See Also==
 
{{AMC12 box|year=2015|ab=B|after=Last Problem|num-b=24}}
 
{{AMC12 box|year=2015|ab=B|after=Last Problem|num-b=24}}
 
{{MAA Notice}}
 
{{MAA Notice}}

Revision as of 13:38, 12 December 2019

Problem

A bee starts flying from point $P_0$. She flies $1$ inch due east to point $P_1$. For $j \ge 1$, once the bee reaches point $P_j$, she turns $30^{\circ}$ counterclockwise and then flies $j+1$ inches straight to point $P_{j+1}$. When the bee reaches $P_{2015}$ she is exactly $a \sqrt{b} + c \sqrt{d}$ inches away from $P_0$, where $a$, $b$, $c$ and $d$ are positive integers and $b$ and $d$ are not divisible by the square of any prime. What is $a+b+c+d$ ?

$\textbf{(A)}\; 2016 \qquad\textbf{(B)}\; 2024 \qquad\textbf{(C)}\; 2032 \qquad\textbf{(D)}\; 2040 \qquad\textbf{(E)}\; 2048$

Solution 1

Let $x = e^{i \pi / 6}$, a $30^\circ$ counterclockwise rotation centered at the origin. Notice that $P_k$ on the complex plane is:

\[1 + 2x + 3x^2 + \cdots + (k+1)x^k\]

We need to find the magnitude of $P_{2015}$ on the complex plane. This is an arithmetic/geometric series.

\begin{align*} S &= 1 + 2x + 3x^2 + \cdots + 2015x^{2014} \\ xS &= x + 2x^2 + 3x^3 + \cdots + 2015x^{2015} \\ (1-x)S &= 1 + x + x^2 + \cdots + x^{2014} - 2015x^{2015} \\ S &= \frac{1 - x^{2015} }{(1-x)^2} - \frac{2015x^{2015}}{1-x} \end{align*}

We want to find $|S|$. First, note that $x^{2015} = x^{11} = x^{-1}$ because $x^{12} = 1$. Therefore

\[S = \frac{1 - \frac{1}{x}}{(1-x)^2} - \frac{2015}{x(1-x)} = -\frac{1}{x(1-x)} - \frac{2015}{x(1-x)} = -\frac{2016}{x(1-x)}.\]

Hence, since $|x|=1$, we have $|S| = \frac{2016}{|1-x|}.$

Now we just have to find $|1-x|$. This can just be computed directly:

\[1 - x = 1 - \frac{\sqrt{3}}{2} - \frac{1}{2}i\]

\[|1-x|^2 = \left(1 - \sqrt{3} + \frac{3}{4} \right) + \frac{1}{4} = 2 - \sqrt{3} = {\left( \frac{\sqrt{6}-\sqrt{2}}{2} \right)}^2\]

\[|1-x| = \frac{\sqrt{6} - \sqrt{2}}{2}.\]

Therefore $|S| = 2016 \cdot \frac{2}{\sqrt{6} -\sqrt{2}} = 2016 \left( \frac{\sqrt{6} + \sqrt{2}}{2} \right) = 1008 \sqrt{2} + 1008 \sqrt{6}.$

Thus the answer is $1008 + 1008 + 2 + 6 = \boxed{\textbf{(B)}\; 2024}.$

Solution 2

Here is an alternate solution that does not use complex numbers:

We will calculate the distance from $P_{2015}$ to $P_0$ using the Pythagorean theorem. Assume $P_0$ lies at the origin, so we will calculate the distance to $P_{2015}$ by calculating the distance traveled in the x-direction and the distance traveled in the y-direction. We can calculate this by summing each movement:

$x=1\cos{0}+2\cos {30}+3\cos {60}+4\cos {90}+5\cos {120}+\cdot \cdot \cdot+2011\cos{180}+2012\cos {210}+2013\cos{240}+2014\cos{270}+2015\cos{300}$

A movement of $p$ units at $q$ degrees is the same thing as a movement of $-p$ units at $q-180$ degrees, so we can adjust all the cosines with arguments greater than 180 as follows:

$x=1\cos{0}+2\cos {30}+3\cos {60}+4\cos {90}+5\cos {120}+6\cos{150}-7\cos{0}-8\cos{30}-\cdot \cdot \cdot -2015 \cos{120}$

Now we group terms with like-cosines and factor out the cosines:

$x=(1-7+13-\cdot \cdot \cdot +2005-2011)\cos{0}+(2-8+14- \cdot \cdot \cdot +2006-2012)\cos{30}+\cdot \cdot \cdot +(5-11+17- \cdot \cdot \cdot +2008-2014)\cos{120}+(6-12+18- \cdot \cdot \cdot -2004+2010)\cos{150}$

Each sum in the parentheses has 336 terms (except the very last one, which has 335), so by pairing each term, we can see that there are $\frac {336}{2}$ pairs of $-6$. So each sum evaluates to $168\cdot -6=-1008$, except the very last sum, which has 167 pairs of $-6$ and an extra 2010, so it evaluates to $167\cdot -6+2010=1008$. Plugging in these values:

$x=-1008\cos{0}-1008\cos{30}-1008\cos{60}-1008\cos{90}-1008\cos{120}+1008\cos{150}$ $x=1008(-1-\frac{\sqrt{3}}{2}-\frac{1}{2}-0+\frac{1}{2}-\frac{\sqrt{3}}{2})=-1008(1+\sqrt{3})$

Now that we have how far was traveled in the x-direction, we need to find how far was traveled in the y-direction. Using the same logic as above, we arrive at the sum:

$y=-1008\sin{0}-1008\sin{30}-1008\sin{60}-1008\sin{90}-1008\sin{120}+1008\sin{150}$

$y=1008(0-\frac{1}{2}-\frac{\sqrt{3}}{2}-1-\frac{\sqrt{3}}{2}+\frac{1}{2})=-1008(1+\sqrt{3})$

The last step is to use the Pythagorean to find the distance from $P_0$. This distance is given by:

$\sqrt{x^2+y^2}=\sqrt{(-1008(1+\sqrt{3}))^2+(-1008(1+\sqrt{3}))^2}=\sqrt{2\cdot 1008^2 \cdot (1+\sqrt{3})^2}=1008(1+\sqrt{3})\sqrt{2}$

Multiplying out, we have $1008\sqrt{2}+1008\sqrt{6}$, so the answer is $1008+2+1008+6= \boxed {\bold {(B)}\; 2024}$.

Solution 3

We first notice that if the bee is turning 30 degrees each turn, it will take 12 turns to be looking in the same direction when the bee initially left. This means we simply need to answer the question; how far will the bee be when the bee is facing in the same direction?


First we use the fact that after 3 turns, the bee will be facing in a direction perpendicular to the the initial direction. From here we can draw a perpendicular from $P_2$ to the line $\overline{P_0P_1}$ intersecting a point $C_0$. We will also place the point $C_1$ at the intersection of $\overline{P_0P_1}$ and $\overline{P_3P_4}$. In addition, the point $C_2$ is placed at the perpendicular dropped from $P_2$ to the line $\overline{P_3C_1}$. We will also set the distance $\overline{P_0P_1} = n$ and thus $\overline{P_1P_2} = n+1$. With this perpendicular we see that the triangle $\triangle{P_1P_2C_0}$ is a 30-60-90 triangle. This means that the length $\overline{P_1C_0} = \frac{(n+1)\sqrt{3}}{2}$ and the length $\overline{C_1C_2} = \frac{n+1}{2}$. We can also see that the triangle $\triangle{P_2C_1P_3}$ is a 30-60-90 triangle and thus $\overline{C_0C_1} = \frac{n+2}{2}$ and $\overline{C_2P_3} = \frac{(n+2)\sqrt{3}}{2}$. Now if we continue this across all $P_i$ and set the point $P_0$ to the coordinates $(0, 0)$. As you can see, we are inherently putting a “box” around the figure. Doing similar calculations for all four “sides” of this spiral we get that the length

\[\overline{P_0C_1} = n + \frac{(n+1)\sqrt{3}}{2} + \frac{n+2}{2}\], \[\overline{C_1C_4} = \frac{(n+1)}{2} + \frac{(n+2)\sqrt{3}}{2} + (n+3) + \frac{(n+4)\sqrt{3}}{2} + \frac{n+5}{2}\], \[\overline{C_4C_7} = \frac{(n+4)}{2} + \frac{(n+5)\sqrt{3}}{2} + (n+6) + \frac{(n+7)\sqrt{3}}{2} + \frac{n+8}{2}\], \[\overline{C_7C_{10}} = \frac{(n+7)}{2} + \frac{(n+8)\sqrt{3}}{2} + (n+9) + \frac{(n+10)\sqrt{3}}{2} + \frac{n+11}{2}\], and finally \[\overline{C_{10}P_{12}} = \frac{(n+10)}{2} + \frac{(n+11)\sqrt{3}}{2}\].

Here the point $C_4$ is defined as the intersection of lines $\overline{P_3P_4}$ and $\overline{P_6P_7}$. The point $C_7$ is defined as the intersection of lines $\overline{P_6P_7}$ and $\overline{P_9P_{10}}$. Finally, the point $C_10$ is defined as the intersection of lines $\overline{P_{9}P_{10}}$ and $\overline{P_{12}P_{13}}$. Note that our spiral stops at $P_{12}$ before the next spiral starts. Calculating the offset from the x and the y direction, we see that the offset, or the new point $P_{12}$, is $({-6}, {-6}-12 \sqrt{3})$. This is an interesting property that the points’ coordinate changes by a constant offset no matter what $n$ is. Since the new point’s subscript changes by 12 each time and we see that 2016 is divisible by 12, the point $P_{2016} = ({-168} \cdot {6}, {168} \cdot ({-6} \sqrt{3} {-12}))$. Using similar 30-60-90 triangle properties, we see that $P_{2015} = ({-6} \cdot 168-1008 \sqrt{3}, 168({-6} \sqrt{3} - 12) + 1008)$. Using the distance formula, the numbers cancel out nicely (1008 is divisible by 168, so take 168 when using the distance formula) and we see that the final answer is $(1008)(1+\sqrt{3})(\sqrt{2})$ which gives us a final answer of $\boxed{2024}$.

-bowmanrocks32


Solution 4

Suppose that the bee makes a move of distance $i$. After 6 turns it will be facing the opposite direction and move $i+6$ units. Combining these opposite movements gives a total movement of $-6$ units. The bee makes a total of $2016=12\cdot 168$ moves, so there are $168$ of these pairs, for each direction the bee faces ($0^\circ, 30^\circ, 60^\circ, 90^\circ, 120^\circ, 150^\circ$). To keep the numbers small, we will multiply by $6\cdot 168=1008$ at the end.

We draw a quick diagram of one unit in each direction. [asy] draw((0,0)--(1,0)--(1+sqrt(3)/2, 1/2)--(3/2+sqrt(3)/2, 1/2+sqrt(3)/2)--(3/2+sqrt(3)/2, 3/2+sqrt(3)/2)--(1+sqrt(3)/2, 3/2+sqrt(3))--(1, 2+sqrt(3))); draw((1,0)--(3/2+sqrt(3)/2, 0), dashed); draw((1,2+sqrt(3))--(3/2+sqrt(3)/2, 2+sqrt(3)), dashed); draw((3/2+sqrt(3)/2, 2+sqrt(3))--(3/2+sqrt(3)/2, 0), dashed); draw((1+sqrt(3)/2,0)--(1+sqrt(3)/2, 1/2)--(3/2+sqrt(3)/2, 1/2), dashed); draw((1+sqrt(3)/2,2+sqrt(3))--(1+sqrt(3)/2, 3/2+sqrt(3))--(3/2+sqrt(3)/2, 3/2+sqrt(3)), dashed); [/asy] Using the 30-60-90 triangles, it is clear that the displacement vector is $\langle 1, 2+\sqrt{3}\rangle$, or the displacement length is $\sqrt{1^2+(2+\sqrt{3})^2}=\sqrt{8+4\sqrt{3}}=\sqrt{2}+\sqrt{6}$. Therefore the total displacement is $\left|-1008\left(\sqrt{2}+\sqrt{6}\right)\right|= 1008\sqrt{2}+1008\sqrt{6}\implies 1008+2+1008+6=\boxed{\text{(B) }2024}$

Solution 5 (big complex bash)

Let $P_0$ be the origin. East would be the real axis in the positive direction. Then we can assign each $P_n$ a complex value. The displacement would then be the magnitude of the complex number.

Notice that after the $n$th move the value of $P_n$ is $P_{n-1}+ne^{\frac{i(n-1)\pi}{6}}$. Also notice that after six moves the bee is facing in the opposite direction. And because we have found a recursion, we can add these up.

Then we have \[P_n=e^{0}+2e^{\frac{i\pi}{6}}+\cdots+2015e^{\frac{2014i\pi}{6}},\] and this becomes \[(1-7+13-\cdots-2011)e^0+(2-8+\cdots-2012)e^{\frac{i\pi}{6}}+\cdots+(6-12+\cdots+2010)e^{\frac{5i\pi}{6}}.\]

Simplifying, we have \[-6\cdot168-6\cdot168e^{\frac{i\pi}{6}}-6\cdot168e^{\frac{2i\pi}{6}}-6\cdot168e^{\frac{3i\pi}{6}}-6\cdot168e^{\frac{4i\pi}{6}}-(2010-6\cdot167)e^{\frac{5i\pi}{6}},\] which eventually simplifies to \[-1008-(2+\sqrt3)1008i,\] and this is a $15-75-90$ triangle which has ratios of $1:(2+\sqrt3):(\sqrt2+\sqrt6)$ so the magnitude is $1008\sqrt2+1008\sqrt6$ and the answer is $1008+2+1008+6=\boxed{\text{(B) }2024}$.

~caroline2023

See Also

2015 AMC 12B (ProblemsAnswer KeyResources)
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