Difference between revisions of "2021 AIME II Problems/Problem 3"

Latest revision as of 03:52, 11 March 2023

Problem

Find the number of permutations $x_1, x_2, x_3, x_4, x_5$ of numbers $1, 2, 3, 4, 5$ such that the sum of five products $x_1x_2x_3 + x_2x_3x_4 + x_3x_4x_5 + x_4x_5x_1 + x_5x_1x_2$ is divisible by $3$ .

Solution 1

Since $3$ is one of the numbers, a product with a $3$ in it is automatically divisible by $3,$ so WLOG $x_3=3,$ we will multiply by $5$ afterward since any of $x_1, x_2, \ldots, x_5$ would be $3,$ after some cancelation we see that now all we need to find is the number of ways that $x_5x_1(x_4+x_2)$ is divisible by $3,$ since $x_5x_1$ is never divisible by $3,$ now we just need to find the number of ways $x_4+x_2$ is divisible by $3.$ Note that $x_2$ and $x_4$ can be $(1, 2), (2, 1), (1, 5), (5, 1), (2, 4), (4, 2), (4, 5),$ or $(5, 4).$ We have $2$ ways to designate $x_1$ and $x_5$ for a total of $8 \cdot 2 = 16.$ So the desired answer is $16 \cdot 5=\boxed{080}.$

~math31415926535

~MathFun1000 (Rephrasing for clarity)

Solution 2 (Cyclic Symmetry and Casework)

The expression $x_1x_2x_3 + x_2x_3x_4 + x_3x_4x_5 + x_4x_5x_1 + x_5x_1x_2$ has cyclic symmetry. Without the loss of generality, let $x_1=3.$ It follows that $\{x_2,x_3,x_4,x_5\}=\{1,2,4,5\}.$ We have:

$x_1x_2x_3 + x_2x_3x_4 + x_3x_4x_5 + x_4x_5x_1 + x_5x_1x_2\equiv x_2x_3x_4 + x_3x_4x_5\pmod{3}.$

$x_2,x_3,x_4,x_5$ are congruent to $1,2,1,2\pmod{3}$ in some order.

We construct the following table for the case $x_1=3,$ with all values in modulo $3:$ $\begin{array}{c||c|c|c|c|c||c} & & & & & & \\ [-2.5ex] \textbf{Row} & \boldsymbol{x_2} & \boldsymbol{x_3} & \boldsymbol{x_4} & \boldsymbol{x_5} & \boldsymbol{x_2x_3x_4 + x_3x_4x_5} & \textbf{Valid?} \\ [0.5ex] \hline & & & & & & \\ [-2ex] 1 & 1 & 1 & 2 & 2 & 0 & \checkmark \\ 2 & 1 & 2 & 1 & 2 & 0 & \checkmark \\ 3 & 1 & 2 & 2 & 1 & 2 & \\ 4 & 2 & 1 & 1 & 2 & 1 & \\ 5 & 2 & 1 & 2 & 1 & 0 & \checkmark \\ 6 & 2 & 2 & 1 & 1 & 0 & \checkmark \end{array}$ For Row 1, $(x_2,x_3)$ can be either $(1,4)$ or $(4,1),$ and $(x_4,x_5)$ can be either $(2,5)$ or $(5,2).$ By the Multiplication Principle, Row 1 produces $2\cdot2=4$ permutations. Similarly, Rows 2, 5, and 6 each produce $4$ permutations.

Together, we get $4\cdot4=16$ permutations for the case $x_1=3.$ By the cyclic symmetry, the cases $x_2=3, x_3=3, x_4=3,$ and $x_5=3$ all have the same count. Therefore, the total number of permutations $x_1, x_2, x_3, x_4, x_5$ is $16\cdot5=\boxed{080}.$

~MRENTHUSIASM

Solution 3

WLOG, let $x_{3} = 3$ So, the terms $x_{1}x_{2}x_{3}, x_{2}x_{3}x_{4},x_{3}x_{4}x_{5}$ are divisible by $3$ .

We are left with $x_{4}x_{5}x_{1}$ and $x_{5}x_{1}x_{2}$ . We need $x_{4}x_{5}x_{1} + x_{5}x_{1}x_{2} \equiv 0 \pmod{3}$ . The only way is when They are $(+1,-1)$ or $(-1, +1) \pmod{3}$ .

The numbers left with us are $1,2,4,5$ which are $+1,-1,+1,-1\pmod{3}$ respectively.

$+1$ (of $x_{4}x_{5}x_{1}$ or $x_{5}x_{1}x_{2}$ ) $= +1 \cdot +1 \cdot +1$ $\;\;\; OR \;\;\;+1$ (of $x_{4}x_{5}x_{1}$ or $x_{5}x_{1}x_{2}$ ) = $-1 \cdot -1 \cdot +1$ .

$-1$ (of $x_{4}x_{5}x_{1}$ or $x_{5}x_{1}x_{2}$ ) $= -1 \cdot -1 \cdot -1$ $\;\;\; OR \;\;\;-1$ (of $x_{4}x_{5}x_{1}$ or $x_{5}x_{1}x_{2}$ ) = $-1 \cdot +1 \cdot +1$

But, as we have just two $+1's$ and two $-1's$ . Hence, We will have to take $+1 = +1 \cdot -1 \cdot -1$ and $-1 = -1 \cdot +1 \cdot +1$ . Among these two, we have a $+1$ and $-1$ in common, i.e. $(x_{5}, x_{1}) = (+1, -1) or (-1, +1)$ (because $x_{1}$ and $x_{5}$ . are common in $x_{4}x_{5}x_{1}$ and $x_{5}x_{1}x_{2}$ ).

So, $(x_{5}, x_{1}) \in {(1,2), (1,5), (4,2), (4,5), (2,1), (5,1), (2,4), (5,4)}$ i.e. $8$ values.

For each value of $(x_{5}, x_{1})$ we get $2$ values for $(x_{2}, x_{4})$ . Hence, in total, we have $8 \times 2 = 16$ ways.

But any of the $x_{i} 's$ can be $3$ . So, $16 \times 5 = \boxed{080}$ .

-Arnav Nigam

Solution 4 (Proportion)

WLOG, let $x_{3} = 3$ . Then: $x_{1}x_{2}x_{3} + x_{2}x_{3}x_{4} + x_{3}x_{4}x_{5} + x_{4}x_{5}x_{1} + x_{5}x_{1}x_{2} = 3 (x_1 x_2 + x_2 x_4 + x_4 x_5) + x_5 x_1 (x_2 + x_4).$ The sum is divisible by $3$ if and only if $x_2 + x_4$ is divisible by $3$ . The possible sums of $x_2 + x_4$ are $1 + 2, 1 + 4, 1 + 5, 2 + 4, 2 + 5, 4 + 5.$ Two of them are not multiples of $3$ , but four of them are multiples.

A total number of permutations is $5! = 120.$

$\frac {2}{3}$ of this number, that is, $80,$ give sums that are multiples of $3.$

vladimir.shelomovskii@gmail.com, vvsss

Solution 5 (Factoring)

This is my first time doing a solution (feel free to edit it)

We have $x_1x_2x_3 + x_2x_3x_4 + x_3x_4x_5 + x_4x_5x_1 + x_5x_1x_2.$

We have $5$ numbers. Considering any $x$ as $3,$ we see that we are left with two terms that are not always divisible by $3,$ which means that already gives us 5 options. Let's now consider $x_1 =3:$ We are left with $3x_2x_3 + x_2x_3x_4 + x_3x_4x_5 + 3x_4x_5 + 3x_5x_2.$ The two terms left over are $x_2x_3x_4 + x_3x_4x_5 \equiv 0 \pmod{3}$ since we already have used $3$ the remaining numbers are $1,2,4,5.$

We now factor $\begin{align*} (x_2 + x_5)(x_3x_4) &\equiv 0 \pmod{3} \\ (x_2 + x_5) &\equiv 0 \pmod{3} \end{align*}$ since $1,2,4,5$ are all not factors of $3.$

Now using the number $1,2,4,5,$ we take two to get a number divisible by $3$ for $(x_2 + x_5):$ $\begin{align*} 1+5 &\equiv 0 \pmod{3}, \\ 4+2 &\equiv 0 \pmod{3}, \\ 4+5 &\equiv 0 \pmod{3}, \\ 1+2 &\equiv 0 \pmod{3}. \end{align*}$ We have $4$ possibilities from above. Since we can also have $5+1$ or $2+4,$ there are $4\cdot2=8$ possibilities in all.

Now using $(x_2 + x_5)(x_3x_4) \equiv 0 \pmod{3},$ we have $(x_3x_4),$ which results in $8$ more possibilities of $2$ times more. So, we get $2\cdot2\cdot4=16.$

Remember that $3$ can be any of $5$ different variables. So, we multiply by $5$ to get the answer $\boxed{080}.$

Video Solution

https://www.youtube.com/watch?v=HikWWhQlkVw

@@ Line 77: / Line 77: @@
 '''vladimir.shelomovskii@gmail.com, vvsss'''
-This is my first time doing a solution(feel free to edit it)
+==Solution 5 (Factoring)==
-We have <cmath>x_1x_2x_3 + x_2x_3x_4 + x_3x_4x_5 + x_4x_5x_1 + x_5x_1x_2</cmath>
+This is my first time doing a solution (feel free to edit it)
-We have 5 numbers consider any x as 3 we see that we are left with two terms that are not always divisble by 3.
+We have <cmath>x_1x_2x_3 + x_2x_3x_4 + x_3x_4x_5 + x_4x_5x_1 + x_5x_1x_2.</cmath>
-Which means that already gives us 5 options.
+We have <math>5</math> numbers. Considering any <math>x</math> as <math>3,</math> we see that we are left with two terms that are not always divisible by <math>3,</math> which means that already gives us 5 options.
+Let's now consider <math>x_1 =3:</math>We are left with <cmath>3x_2x_3 + x_2x_3x_4 + x_3x_4x_5 + 3x_4x_5 + 3x_5x_2.</cmath>
-Lets now consider <cmath>x_1</cmath> =3
-we are left with <cmath>3x_2x_3 + x_2x_3x_4 + x_3x_4x_5 + 3x_4x_5 + 3x_5x_2</cmath>
 The two terms left over are
-<cmath>x_2x_3x_4 + x_3x_4x_5</cmath> = 0 mod(3)
+<cmath>x_2x_3x_4 + x_3x_4x_5 \equiv 0 \pmod{3}</cmath>
-since we already have used 3 the remaining numbers are 1,2,4,5
+since we already have used <math>3</math> the remaining numbers are <math>1,2,4,5.</math>
 We now factor
-<cmath>(x_2 + x_5)(x_3x_4)</cmath> = 0 mod(3)
+<cmath>\begin{align*}
-Since 1,2,4,5 are all not factors of 3
+(x_2 + x_5)(x_3x_4) &\equiv 0 \pmod{3} \\
-it means
+(x_2 + x_5) &\equiv 0 \pmod{3}
-<cmath>(x_2 + x_5)</cmath> = 0 mod(3)
+\end{align*}</cmath>
+since <math>1,2,4,5</math> are all not factors of <math>3.</math>
-Now using the number 1,2,4,5
-we take two to get a number divisble by 3
-<cmath>(x_2 + x_5)</cmath>
-+5 = 0 mod(3)
-+2 = 0 mod(3)
-+5 = 0 mod(3)
-+2 = 0 mod(3)
-We have 4 possiblities
-since we can also have
-+1 or 2+4
-we have 2 times 4 possiblities
-Now using <cmath>(x_2 + x_5)(x_3x_4)</cmath> = 0 mod(3)
+Now using the number <math>1,2,4,5,</math> we take two to get a number divisible by <math>3</math> for <math>(x_2 + x_5):</math>
-We have <cmath>(x_3x_4)</cmath>
+<cmath>\begin{align*}
-which reuslts in 8 more possiblities of 2 times more
++5 &\equiv 0 \pmod{3}, \\
-times 2 times 4 which is equal to 16
++2 &\equiv 0 \pmod{3}, \\
++5 &\equiv 0 \pmod{3}, \\
++2 &\equiv 0 \pmod{3}.
+\end{align*}</cmath>
+We have <math>4</math> possibilities from above. Since we can also have <math>5+1</math> or <math>2+4,</math> there are <math>4\cdot2=8</math> possibilities in all.
-remember that 3 can be any of 5 different varriables
+Now using <cmath>(x_2 + x_5)(x_3x_4) \equiv 0 \pmod{3},</cmath> we have <math>(x_3x_4),</math> which results in <math>8</math> more possibilities of <math>2</math> times more. So, we get <math>2\cdot2\cdot4=16.</math>
-so multiple by 5
-times 16 is equal to 80
+Remember that <math>3</math> can be any of <math>5</math> different variables. So, we multiply by <math>5</math> to get the answer <math>\boxed{080}.</math>
 ==Video Solution==

2021 AIME II (Problems • Answer Key • Resources)
Preceded by Problem 2	Followed by Problem 4
1 • 2 • 3 • 4 • 5 • 6 • 7 • 8 • 9 • 10 • 11 • 12 • 13 • 14 • 15
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