Difference between revisions of "2015 AMC 10B Problems/Problem 24"
Sleepypuppy (talk | contribs) (→Solution 1) |
|||
(9 intermediate revisions by 3 users not shown) | |||
Line 20: | Line 20: | ||
If we substitute <math>k = 22</math> into the equation: <math>44(45) = 1980 < 2015</math>. So he has <math>35</math> moves to go. This makes him end up at <math>(-22+35,-22) = (13,-22) \implies \boxed{\textbf{(D)} (13, -22)}</math>. | If we substitute <math>k = 22</math> into the equation: <math>44(45) = 1980 < 2015</math>. So he has <math>35</math> moves to go. This makes him end up at <math>(-22+35,-22) = (13,-22) \implies \boxed{\textbf{(D)} (13, -22)}</math>. | ||
− | |||
− | |||
− | |||
==Solution 2== | ==Solution 2== | ||
Line 37: | Line 34: | ||
==Solution 3== | ==Solution 3== | ||
Looking at his steps, we see that he walks in a spiral shape. At the <math>8</math>th step, he is on the bottom right corner of the <math>3\times 3</math> square centered on the origin. On the <math>24</math>th step, he is on the bottom right corner of the <math>5\times 5</math> square centered at the origin. It seems that the <math>p_{n^2-1}</math> is the bottom right corner of the <math>n\times n</math> square. This makes sense since, after <math>n^2-1</math>, he has been on <math>n^2</math> dots, including the point <math>p_0</math>. Also, this is only for odd <math>n</math>, because starting with the <math>1\times 1</math> square, we can only add one extra set of dots to each side, so we cannot get even <math>n</math>. Since <math>45^2=2025</math>, <math>p_{2024}</math> is the bottom right corner of the <math>45\times 45</math> square. This point is <math>\frac{45-1}{2}=22</math> over to the right, and therefore <math>22</math> down, so <math>p_{2024}=(22, -22)</math>. Since <math>p_{2024}</math> is <math>9</math> ahead of <math>p_{2015}</math>, we go back <math>9</math> spaces to <math>\boxed{\textbf{(D)}\; (13, -22)}</math>. | Looking at his steps, we see that he walks in a spiral shape. At the <math>8</math>th step, he is on the bottom right corner of the <math>3\times 3</math> square centered on the origin. On the <math>24</math>th step, he is on the bottom right corner of the <math>5\times 5</math> square centered at the origin. It seems that the <math>p_{n^2-1}</math> is the bottom right corner of the <math>n\times n</math> square. This makes sense since, after <math>n^2-1</math>, he has been on <math>n^2</math> dots, including the point <math>p_0</math>. Also, this is only for odd <math>n</math>, because starting with the <math>1\times 1</math> square, we can only add one extra set of dots to each side, so we cannot get even <math>n</math>. Since <math>45^2=2025</math>, <math>p_{2024}</math> is the bottom right corner of the <math>45\times 45</math> square. This point is <math>\frac{45-1}{2}=22</math> over to the right, and therefore <math>22</math> down, so <math>p_{2024}=(22, -22)</math>. Since <math>p_{2024}</math> is <math>9</math> ahead of <math>p_{2015}</math>, we go back <math>9</math> spaces to <math>\boxed{\textbf{(D)}\; (13, -22)}</math>. | ||
+ | |||
+ | ==Solution 4 (similar to 3)== | ||
+ | We call <math>p_0</math> the first point, <math>p_1</math> the second, and so on. As in Solution 3, we see that he walks in a counterclockwise spiral. We see that his path is traced out by a series of squares with odd-length sides that contain each other. At step <math>3^2=9,</math> he is at <math>(1,-1)</math>; at step <math>5^2=25,</math> he is at <math>(2,-2)</math>; and so on. We see that at step <math>n^2</math> where <math>n</math> is an odd number, he is at <math>(x,-x)</math> where <math>x=\dfrac{n-1}2.</math> The closest <math>n^2</math> to <math>2016</math> (we want <math>p_{2015},</math> which is the <math>2016</math>th step) is <math>45^2=2025,</math> so we let <math>n=45.</math> On the <math>45^2=2025</math>th step, <math>x=\dfrac{45-1}2=22,</math> so he is at <math>(22,-22).</math> We see that he approached <math>(22,-22)</math> from the left, so backtrack <math>2025-2016=9</math> steps to the left (i.e. subtracting <math>9</math> from the x-coordinate). Thus, we have <math>(22-9,-22)=\boxed{\textbf{(D)}~(13,-22).}</math> | ||
+ | ~Technodoggo | ||
+ | |||
+ | ==Solution 5 (Similar to Solution 1)== | ||
+ | The first thing is to see the amount of footsteps at points <math>(k,k)</math> | ||
+ | |||
+ | We see that at <math>(1,1)</math> he has taken 2 footsteps. | ||
+ | |||
+ | To get to <math>(2,2)</math>, Aaron takes <math>2</math> steps West, <math>2</math> steps South, <math>3</math> steps East, and <math>3</math> steps North. | ||
+ | |||
+ | We can think about this in the following way. For Aaron to get from <math>(k,k)</math> to <math>(k+1,k+1)</math>, he takes <math>2k+2k+(2k+1)+(2k+1)</math> steps = <math>8k+2</math> steps | ||
+ | |||
+ | We can find the total steps taken to get to a point <math>(k+1,k+1)</math> | ||
+ | |||
+ | <math>2+10+18... +8k+2</math> = <math>(4k+2)(k+1</math>) works as a formula | ||
+ | |||
+ | We find that to get to <math>(22,22)</math> this is 2+10+18...+ (4(21)+2)(21)= 1892. We then simply go <math>88</math> steps to get to <math>(-22,-22)</math> | ||
+ | |||
+ | and <math>35</math> more to get to the 2015th step at <math>(13,-22)</math> or answer D | ||
+ | |||
+ | ==Solution 6== | ||
+ | If we graph <math>p_n</math> for a few values of <math>n</math>, we begin to see a particular pattern for <math>p_n</math> when <math>n</math> is a perfect square. For example, <math>p_0=(0,0)</math>, <math>p_4=(-1,1)</math>, <math>p_{16}=(2,-2)</math>, and so on. Similarly, <math>p_1=(1,0)</math>, <math>p_9=(2,-1)</math>, <math>p_{25}=(3,-2)</math>, and so on. Using this, we can generate a pattern for even and odd squares: <cmath>p_{(2n)^2}=(-n, n)</cmath> <cmath>p_{(2n+1)^2}=(n+1,-n)</cmath> | ||
+ | |||
+ | We notice that <math>p_{2015}</math> is quite close to <math>p_{2025}=p_{45^2}</math>. By the same pattern for odd squares, <math>p_{2025}=(23,-22)</math>. <math>p_{2015}</math> is just <math>10</math> units to the left of <math>p_{2025}</math>. Therefore, <math>p_{2015}=\boxed{\textbf{(D) }(13,-22)}</math>. | ||
+ | |||
+ | ~[https://artofproblemsolving.com/wiki/index.php/User:Sid2012 sid2012] | ||
==See Also== | ==See Also== | ||
{{AMC10 box|year=2015|ab=B|num-b=23|num-a=25}} | {{AMC10 box|year=2015|ab=B|num-b=23|num-a=25}} | ||
{{MAA Notice}} | {{MAA Notice}} |
Latest revision as of 22:36, 4 November 2024
Contents
Problem
Aaron the ant walks on the coordinate plane according to the following rules. He starts at the origin facing to the east and walks one unit, arriving at . For , right after arriving at the point , if Aaron can turn left and walk one unit to an unvisited point , he does that. Otherwise, he walks one unit straight ahead to reach . Thus the sequence of points continues , and so on in a counterclockwise spiral pattern. What is ?
Solution 1
The first thing we would do is track Aaron's footsteps:
He starts by taking step East and step North, ending at after steps and about to head West.
Then he takes steps West and steps South, ending at ) after steps, and about to head East.
Then he takes steps East and steps North, ending at after steps, and about to head West.
Then he takes steps West and steps South, ending at after steps, and about to head East.
From this pattern, we can notice that for any integer he's at after steps, and about to head East. There are terms in the sum, with an average value of , so:
If we substitute into the equation: . So he has moves to go. This makes him end up at .
Solution 2
We are given that Aaron starts at , and we note that his net steps follow the pattern of in the -direction, in the -direction, in the -direction, in the -direction, in the -direction, in the -direction, and so on, where we add odd and subtract even.
We want , but it does not work out cleanly. Instead, we get that , which means that there are extra steps past adding in the -direction (and the final number we add in the -direction is ).
So .
We can group as .
Thus .
Solution 3
Looking at his steps, we see that he walks in a spiral shape. At the th step, he is on the bottom right corner of the square centered on the origin. On the th step, he is on the bottom right corner of the square centered at the origin. It seems that the is the bottom right corner of the square. This makes sense since, after , he has been on dots, including the point . Also, this is only for odd , because starting with the square, we can only add one extra set of dots to each side, so we cannot get even . Since , is the bottom right corner of the square. This point is over to the right, and therefore down, so . Since is ahead of , we go back spaces to .
Solution 4 (similar to 3)
We call the first point, the second, and so on. As in Solution 3, we see that he walks in a counterclockwise spiral. We see that his path is traced out by a series of squares with odd-length sides that contain each other. At step he is at ; at step he is at ; and so on. We see that at step where is an odd number, he is at where The closest to (we want which is the th step) is so we let On the th step, so he is at We see that he approached from the left, so backtrack steps to the left (i.e. subtracting from the x-coordinate). Thus, we have ~Technodoggo
Solution 5 (Similar to Solution 1)
The first thing is to see the amount of footsteps at points
We see that at he has taken 2 footsteps.
To get to , Aaron takes steps West, steps South, steps East, and steps North.
We can think about this in the following way. For Aaron to get from to , he takes steps = steps
We can find the total steps taken to get to a point
= ) works as a formula
We find that to get to this is 2+10+18...+ (4(21)+2)(21)= 1892. We then simply go steps to get to
and more to get to the 2015th step at or answer D
Solution 6
If we graph for a few values of , we begin to see a particular pattern for when is a perfect square. For example, , , , and so on. Similarly, , , , and so on. Using this, we can generate a pattern for even and odd squares:
We notice that is quite close to . By the same pattern for odd squares, . is just units to the left of . Therefore, .
See Also
2015 AMC 10B (Problems • Answer Key • Resources) | ||
Preceded by Problem 23 |
Followed by Problem 25 | |
1 • 2 • 3 • 4 • 5 • 6 • 7 • 8 • 9 • 10 • 11 • 12 • 13 • 14 • 15 • 16 • 17 • 18 • 19 • 20 • 21 • 22 • 23 • 24 • 25 | ||
All AMC 10 Problems and Solutions |
The problems on this page are copyrighted by the Mathematical Association of America's American Mathematics Competitions.