Difference between revisions of "2000 AMC 12 Problems/Problem 8"

(Solution 1)
(Solution 7 (Newton’s little formula))
 
(35 intermediate revisions by 15 users not shown)
Line 1: Line 1:
 
{{duplicate|[[2000 AMC 12 Problems|2000 AMC 12 #8]] and [[2000 AMC 10 Problems|2000 AMC 10 #12]]}}
 
{{duplicate|[[2000 AMC 12 Problems|2000 AMC 12 #8]] and [[2000 AMC 10 Problems|2000 AMC 10 #12]]}}
=Problem=
+
==Problem==
  
 
Figures <math>0</math>, <math>1</math>, <math>2</math>, and <math>3</math> consist of <math>1</math>, <math>5</math>, <math>13</math>, and <math>25</math> nonoverlapping unit squares, respectively. If the pattern were continued, how many nonoverlapping unit squares would there be in figure 100?
 
Figures <math>0</math>, <math>1</math>, <math>2</math>, and <math>3</math> consist of <math>1</math>, <math>5</math>, <math>13</math>, and <math>25</math> nonoverlapping unit squares, respectively. If the pattern were continued, how many nonoverlapping unit squares would there be in figure 100?
Line 27: Line 27:
  
  
<math>\mathrm{(A)}\ 10401 \qquad\mathrm{(B)}\ 19801 \qquad\mathrm{(C)}\ 20201 \qquad\mathrm{(D)}\ 39801 \qquad\mathrm{(E)}\ 40801</math>
+
<math>\textbf{(A)}\ 10401 \qquad\textbf{(B)}\ 19801 \qquad\textbf{(C)}\ 20201 \qquad\textbf{(D)}\ 39801 \qquad\textbf{(E)}\ 40801</math>
  
==Solution 1==
+
==Video:==
 +
https://www.youtube.com/watch?v=HVP6qjKAkjA&t=2s
  
We can divide up figure <math>n</math> to get the sum of the sum of the first <math>n+1</math> odd numbers and the sum of the first <math>n</math> odd numbers. If you do not see this, here is the example for <math>n=3</math>:
+
== Solution 1 ==
 +
We can attempt <math>0^2+1^2=1</math> and <math>1^2+2^2=5</math>, so the pattern here looks like the number of squares in the <math>n</math>-th figure is <math>n^2+(n+1)^2</math>*. When we plug in 100 for <math>n</math>, we get <math>100^2+101^2=10000+10201=20201</math>, or option <math>\textbf{(C)}</math>.
  
<asy>
+
==Solution 2==
draw((3,0)--(4,0)--(4,7)--(3,7)--cycle);
 
draw((0,3)--(7,3)--(7,4)--(0,4)--cycle);
 
draw((2,1)--(5,1)--(5,6)--(2,6)--cycle);
 
draw((1,2)--(6,2)--(6,5)--(1,5)--cycle);
 
draw((3,0)--(3,7));
 
</asy>
 
 
 
The sum of the first <math>n</math> odd numbers is <math>n^2</math>, so for figure <math>n</math>, there are <math>(n+1)^2+n^2</math> unit squares. We plug in <math>n=100</math> to get <math>\boxed{\textbf{(C) }20201}</math>.
 
 
 
===Solution 2===
 
  
 
Using the recursion from solution 1, we see that the first differences of <math>4, 8, 12, ...</math> form an arithmetic progression, and consequently that the second differences are constant and all equal to <math>4</math>.  Thus, the original sequence can be generated from a quadratic function.
 
Using the recursion from solution 1, we see that the first differences of <math>4, 8, 12, ...</math> form an arithmetic progression, and consequently that the second differences are constant and all equal to <math>4</math>.  Thus, the original sequence can be generated from a quadratic function.
Line 73: Line 65:
 
Calculating the answer to our problem, <math>f(100) = 20000 + 200 + 1 = 20201</math>, which is choice <math>\boxed{\textbf{(C) }20201}</math>.
 
Calculating the answer to our problem, <math>f(100) = 20000 + 200 + 1 = 20201</math>, which is choice <math>\boxed{\textbf{(C) }20201}</math>.
  
===Solution 3===
+
==Solution 3==
 
We can see that each figure <math>n</math> has a central box and 4 columns of <math>n</math> boxes on each side of each square. Therefore, at figure 100, there is a central box with 100 boxes on the top, right, left, and bottom. Knowing that each quarter of each figure has a pyramid structure, we know that for each quarter there are <math>\sum_{n=1}^{100} n = 5050</math> squares. <math>4 \cdot 5050 = 20200</math>. Adding in the original center box we have <math> 20200 + 1 = \boxed{\textbf{(C) }20201}</math>.
 
We can see that each figure <math>n</math> has a central box and 4 columns of <math>n</math> boxes on each side of each square. Therefore, at figure 100, there is a central box with 100 boxes on the top, right, left, and bottom. Knowing that each quarter of each figure has a pyramid structure, we know that for each quarter there are <math>\sum_{n=1}^{100} n = 5050</math> squares. <math>4 \cdot 5050 = 20200</math>. Adding in the original center box we have <math> 20200 + 1 = \boxed{\textbf{(C) }20201}</math>.
  
===Solution 4===
+
==Solution 4==
 
Let <math>a_n</math> be the number of squares in figure <math>n</math>.  We can easily see that  
 
Let <math>a_n</math> be the number of squares in figure <math>n</math>.  We can easily see that  
 
<cmath>a_0=4\cdot 0+1</cmath>
 
<cmath>a_0=4\cdot 0+1</cmath>
Line 82: Line 74:
 
<cmath>a_2=4\cdot 3+1</cmath>
 
<cmath>a_2=4\cdot 3+1</cmath>
 
<cmath>a_3=4\cdot 6+1.</cmath>
 
<cmath>a_3=4\cdot 6+1.</cmath>
 +
See that we multiply the number we are on to the next consecutive number.
 
Note that in <math>a_n</math>, the number multiplied by the 4 is the <math>n</math>th triangular number.  Hence, <math>a_{100}=4\cdot \frac{100\cdot 101}{2}+1=\boxed{\textbf{(C) }20201}</math>.
 
Note that in <math>a_n</math>, the number multiplied by the 4 is the <math>n</math>th triangular number.  Hence, <math>a_{100}=4\cdot \frac{100\cdot 101}{2}+1=\boxed{\textbf{(C) }20201}</math>.
~qkddud~
+
~ edited by mathlover66
 +
 
 +
==Solution 5==
 +
Let <math>f_n</math> denote the number of unit cubes in a figure. We have
 +
<cmath>f_0=1</cmath>
 +
<cmath>f_1=5</cmath>
 +
<cmath>f_2=13</cmath>
 +
<cmath>f_3=25</cmath>
 +
<cmath>f_4=41</cmath>
 +
<cmath>...</cmath>
 +
 
 +
Computing the difference between the number of cubes in each figure yields
 +
<cmath>4,8,12,16,...</cmath>
 +
It is easy to notice that this is an arithmetic sequence, with the first term being <math>4</math> and the difference being <math>4</math>. Let this sequence be <math>a_n</math>
 +
 
 +
From <math>f_0</math> to <math>f_{100}</math>, the sequence will have <math>100</math> terms. Using the arithmetic sum formula yields
 +
 
 +
<cmath>S_{100}=\frac{100[2\cdot 4+(100-1)4]}{2}</cmath>
 +
<cmath>=50(2\cdot 4+99\cdot 4)</cmath>
 +
<cmath>=50(101\cdot 4)</cmath>
 +
<cmath>=200\cdot 101</cmath>
 +
<cmath>=20200</cmath>
 +
 
 +
So <math>f_{100}=1+20200=\boxed{\textbf{(C) }20201}</math> unit cubes.
 +
 
 +
~ljlbox
 +
 
 +
== Solution 6 (Newton's Forward Differences) ==
 +
We know that 1 and 5 differ by 4, 5 and 13 differ by 8, and 13 and 25 differ by 12. Hence the differences are 4, 8, and 12, resp. And the differences of the differences area all 4. So by Newton's Forward Difference Formula, we get the 100th figure is(because Figure 0 exists) <math>\dbinom{101-1}{0}+4\dbinom{101-1}{1}+4\dbinom{101-1}{2}=20201</math> or <math>\textbf{(C)}</math>
 +
-vsamc
 +
 
 +
 
 +
== Solution 7 (Newton’s little formula) ==
 +
Newton’s little formula states that <math>a_n = A \binom{n-1}{0} + B \binom{n-1}{1} + C \binom{n-1}{2} + \cdots + K \binom{n-1}{m}</math> if first term is <math>a_1</math> and <math>A =</math> first difference, <math>B =</math> second difference, and so on. Hence we apply the formula (because we start at term 0, term 100 is <math>a_{101}</math>): <math>a_{101} = 5 \binom{100}{0} + 8 \binom{100}{1} + 4 \binom{100}{2} = \boxed{20201} = \textbf{(C)}.</math>
 +
~Peelybonehead
 +
~clarification by LeonidasTheConquerer
 +
 
 +
== Solution 8 (geometrical intuition) ==
 +
By taking figure <math>n</math>, putting the centers of each square on a grid, and rotating the figure 45 degrees, we get the following shape (figure 3 is shown for reference):
 +
<asy>
 +
import olympiad;
 +
 
 +
int fig = 3;
 +
 
 +
for (int i = 0; i <= 2*fig; ++i) {
 +
  for (int j = 0; j <= 2*fig; ++j) {
 +
    pair p = (i, j);
 +
    //do we need this point?
 +
    if ((i+j)%2 == 1) {
 +
      continue;
 +
    }
 +
    //draw squares
 +
    draw((p+N)--(p+E)--(p+S)--(p+W)--cycle);
 +
    //draw lattices
 +
    if (i < 2*fig-1) {
 +
      draw(p--p+2*E, red);
 +
    }
 +
    if (j < 2*fig-1) {
 +
      draw(p--p+2*N, red);
 +
    }
 +
    //mark center points
 +
    if (i % 2 == 0) {
 +
      dot(p, green);
 +
    } else {
 +
      dot(p, blue);
 +
    }
 +
  }
 +
}
 +
</asy>
 +
There are two lattices of points (shown in red): one of side length <math>n</math> (blue) and one of <math>n+1</math> (green). The rest follows like in solution 1.
 +
 
 +
-[[User:Integralarefun|Integralarefun]] ([[User talk:Integralarefun|talk]]) 18:21, 29 July 2023 (EDT)
  
 
==See Also==
 
==See Also==
Line 89: Line 153:
 
{{AMC12 box|year=2000|num-b=7|num-a=9}}
 
{{AMC12 box|year=2000|num-b=7|num-a=9}}
 
{{AMC10 box|year=2000|num-b=11|num-a=13}}
 
{{AMC10 box|year=2000|num-b=11|num-a=13}}
 
+
[[Category:Introductory Geometry Problems]]
 
[[Category:Introductory Algebra Problems]]
 
[[Category:Introductory Algebra Problems]]
 
{{MAA Notice}}
 
{{MAA Notice}}

Latest revision as of 16:35, 16 January 2024

The following problem is from both the 2000 AMC 12 #8 and 2000 AMC 10 #12, so both problems redirect to this page.

Problem

Figures $0$, $1$, $2$, and $3$ consist of $1$, $5$, $13$, and $25$ nonoverlapping unit squares, respectively. If the pattern were continued, how many nonoverlapping unit squares would there be in figure 100?

[asy] unitsize(8); draw((0,0)--(1,0)--(1,1)--(0,1)--cycle); draw((9,0)--(10,0)--(10,3)--(9,3)--cycle); draw((8,1)--(11,1)--(11,2)--(8,2)--cycle); draw((19,0)--(20,0)--(20,5)--(19,5)--cycle); draw((18,1)--(21,1)--(21,4)--(18,4)--cycle); draw((17,2)--(22,2)--(22,3)--(17,3)--cycle); draw((32,0)--(33,0)--(33,7)--(32,7)--cycle); draw((29,3)--(36,3)--(36,4)--(29,4)--cycle); draw((31,1)--(34,1)--(34,6)--(31,6)--cycle); draw((30,2)--(35,2)--(35,5)--(30,5)--cycle); label("Figure",(0.5,-1),S); label("$0$",(0.5,-2.5),S); label("Figure",(9.5,-1),S); label("$1$",(9.5,-2.5),S); label("Figure",(19.5,-1),S); label("$2$",(19.5,-2.5),S); label("Figure",(32.5,-1),S); label("$3$",(32.5,-2.5),S); [/asy]


$\textbf{(A)}\ 10401 \qquad\textbf{(B)}\ 19801 \qquad\textbf{(C)}\ 20201 \qquad\textbf{(D)}\ 39801 \qquad\textbf{(E)}\ 40801$

Video:

https://www.youtube.com/watch?v=HVP6qjKAkjA&t=2s

Solution 1

We can attempt $0^2+1^2=1$ and $1^2+2^2=5$, so the pattern here looks like the number of squares in the $n$-th figure is $n^2+(n+1)^2$*. When we plug in 100 for $n$, we get $100^2+101^2=10000+10201=20201$, or option $\textbf{(C)}$.

Solution 2

Using the recursion from solution 1, we see that the first differences of $4, 8, 12, ...$ form an arithmetic progression, and consequently that the second differences are constant and all equal to $4$. Thus, the original sequence can be generated from a quadratic function.

If $f(n) = an^2 + bn + c$, and $f(0) = 1$, $f(1) = 5$, and $f(2) = 13$, we get a system of three equations in three variables:

$f(0) = 1$ gives $c = 1$

$f(1) = 5$ gives $a + b + c = 5$

$f(2) = 13$ gives $4a + 2b + c = 13$

Plugging in $c=1$ into the last two equations gives

$a + b = 4$

$4a + 2b = 12$

Dividing the second equation by 2 gives the system:

$a + b = 4$

$2a + b = 6$

Subtracting the first equation from the second gives $a = 2$, and hence $b = 2$. Thus, our quadratic function is:

$f(n) = 2n^2 + 2n + 1$

Calculating the answer to our problem, $f(100) = 20000 + 200 + 1 = 20201$, which is choice $\boxed{\textbf{(C) }20201}$.

Solution 3

We can see that each figure $n$ has a central box and 4 columns of $n$ boxes on each side of each square. Therefore, at figure 100, there is a central box with 100 boxes on the top, right, left, and bottom. Knowing that each quarter of each figure has a pyramid structure, we know that for each quarter there are $\sum_{n=1}^{100} n = 5050$ squares. $4 \cdot 5050 = 20200$. Adding in the original center box we have $20200 + 1 = \boxed{\textbf{(C) }20201}$.

Solution 4

Let $a_n$ be the number of squares in figure $n$. We can easily see that \[a_0=4\cdot 0+1\] \[a_1=4\cdot 1+1\] \[a_2=4\cdot 3+1\] \[a_3=4\cdot 6+1.\] See that we multiply the number we are on to the next consecutive number. Note that in $a_n$, the number multiplied by the 4 is the $n$th triangular number. Hence, $a_{100}=4\cdot \frac{100\cdot 101}{2}+1=\boxed{\textbf{(C) }20201}$. ~ edited by mathlover66

Solution 5

Let $f_n$ denote the number of unit cubes in a figure. We have \[f_0=1\] \[f_1=5\] \[f_2=13\] \[f_3=25\] \[f_4=41\] \[...\]

Computing the difference between the number of cubes in each figure yields \[4,8,12,16,...\] It is easy to notice that this is an arithmetic sequence, with the first term being $4$ and the difference being $4$. Let this sequence be $a_n$

From $f_0$ to $f_{100}$, the sequence will have $100$ terms. Using the arithmetic sum formula yields

\[S_{100}=\frac{100[2\cdot 4+(100-1)4]}{2}\] \[=50(2\cdot 4+99\cdot 4)\] \[=50(101\cdot 4)\] \[=200\cdot 101\] \[=20200\]

So $f_{100}=1+20200=\boxed{\textbf{(C) }20201}$ unit cubes.

~ljlbox

Solution 6 (Newton's Forward Differences)

We know that 1 and 5 differ by 4, 5 and 13 differ by 8, and 13 and 25 differ by 12. Hence the differences are 4, 8, and 12, resp. And the differences of the differences area all 4. So by Newton's Forward Difference Formula, we get the 100th figure is(because Figure 0 exists) $\dbinom{101-1}{0}+4\dbinom{101-1}{1}+4\dbinom{101-1}{2}=20201$ or $\textbf{(C)}$ -vsamc


Solution 7 (Newton’s little formula)

Newton’s little formula states that $a_n = A \binom{n-1}{0} + B \binom{n-1}{1} + C \binom{n-1}{2} + \cdots + K \binom{n-1}{m}$ if first term is $a_1$ and $A =$ first difference, $B =$ second difference, and so on. Hence we apply the formula (because we start at term 0, term 100 is $a_{101}$): $a_{101} = 5 \binom{100}{0} + 8 \binom{100}{1} + 4 \binom{100}{2} = \boxed{20201} = \textbf{(C)}.$ ~Peelybonehead ~clarification by LeonidasTheConquerer

Solution 8 (geometrical intuition)

By taking figure $n$, putting the centers of each square on a grid, and rotating the figure 45 degrees, we get the following shape (figure 3 is shown for reference): [asy] import olympiad;  int fig = 3;  for (int i = 0; i <= 2*fig; ++i) {   for (int j = 0; j <= 2*fig; ++j) {     pair p = (i, j);     //do we need this point?     if ((i+j)%2 == 1) {       continue;     }     //draw squares     draw((p+N)--(p+E)--(p+S)--(p+W)--cycle);     //draw lattices     if (i < 2*fig-1) {       draw(p--p+2*E, red);     }     if (j < 2*fig-1) {       draw(p--p+2*N, red);     }     //mark center points     if (i % 2 == 0) {       dot(p, green);     } else {       dot(p, blue);     }   } } [/asy] There are two lattices of points (shown in red): one of side length $n$ (blue) and one of $n+1$ (green). The rest follows like in solution 1.

-Integralarefun (talk) 18:21, 29 July 2023 (EDT)

See Also

2000 AMC 12 (ProblemsAnswer KeyResources)
Preceded by
Problem 7
Followed by
Problem 9
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 12 Problems and Solutions
2000 AMC 10 (ProblemsAnswer KeyResources)
Preceded by
Problem 11
Followed by
Problem 13
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. AMC logo.png