Difference between revisions of "1965 AHSME Problems/Problem 40"

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We can then try <math>(x^2+3x+1)=x^4+6x^3+11x^2+6x+1</math>.  
 
We can then try <math>(x^2+3x+1)=x^4+6x^3+11x^2+6x+1</math>.  
<cmath>P=(x^2+3x)^2-3(x+10)</cmath>
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<cmath>P=(x^2+3x+1)^2-3(x-10)</cmath>
 
This is much more useful, as it moves all non-linear terms inside of a squared expression.
 
This is much more useful, as it moves all non-linear terms inside of a squared expression.
  

Latest revision as of 23:42, 21 October 2021

Problem

Let $n$ be the number of integer values of $x$ such that $P = x^4 + 6x^3 + 11x^2 + 3x + 31$ is the square of an integer. Then $n$ is:

$\textbf{(A)}\ 4 \qquad  \textbf{(B) }\ 3 \qquad  \textbf{(C) }\ 2 \qquad  \textbf{(D) }\ 1 \qquad  \textbf{(E) }\ 0$


Solution

First, we wish to factor $P$ into a more manageable form. From the beginning of $P$, we notice $x^4+6x^3$, which gives us the idea to use $(x^2+3x)^2=x^4+6x^3+9x^2$.

This gives us \[P=(x^2+3x)^2+2x^2+3x+31\] This is not useful, but it gives us a place to start from.

We can then try $(x^2+3x+1)=x^4+6x^3+11x^2+6x+1$. \[P=(x^2+3x+1)^2-3(x-10)\] This is much more useful, as it moves all non-linear terms inside of a squared expression.

We can then say $P=(x^2+3x+1)^2-3(x-10)=a^2$, where $a^2$ is the square of an integer mentioned on the problem. Right from here, we can set $x=10$, which cancels out the $3(x-10)$, giving $(100+30+1)^2=a^2$. This gives us one solution, $x=10$, $a=131$.


We can then rearrange the expression, giving us $(x^2+3x+1)^2-a^2=3(x-10)$. Factoring using difference of squares, we obtain \[(x^2+3x+1+|a|)(x^2+3x+1-|a|)=3(x-10)\]

We can then state that when $x$ is greater than $3$ and less than $-9$, $x^2+3x+1$ will be greater than $|3x-10|$. This is obtained by setting $x^2+3x+1>|3x-10|$ and then solving the inequality. We can then conclude that $x^2+3x+1+|a|>|3x-10|$.

Next, we claim that $x^2+3x+1-|a| \geq 1$ or $x^2+3x+1-|a| \leq -1$ when $x \neq 10$. We can prove this by first noting that since $x$ and $a$ are integers, $x^2+3x+1-|a|$ is an integer. Next, we shall assume that $x^2+3x+1-|a|=0$. Solving this and plugging back into the original equation, we obtain $(2|a|)(0)=3(x-10)$. Solving we obtain $x=10$, which is a contraction to $x \neq 10$. Therefore, $x^2+3x+1-|a| \neq 0$ and $x^2+3x+1-|a| \geq 1$ or $x^2+3x+1-|a| \leq -1$.

Finally, we can go back to the equation \[(x^2+3x+1+|a|)(x^2+3x+1-|a|)=3(x-10)\] We note that since $(x^2+3x+1+|a|)$ is larger than $3(x-10)$, in order for there to be solutions, $(x^2+3x+1-|a|)$ must be in the range $(-1,1)$. However, this contradicts what was proven earlier, so when $x \neq 10$ and $x < -9$ or $x > 3$, there are no solutions for $x$.


Now, all that remains to be checked are values of $x$ between $-9$ and $3$. Using brute force and checking each value individually, we can assert that there are no such solutions for $x$, leaving us with only $1$ solution, $x=10$. Therefore, the answer is $\boxed{(D) }$

Solution by treetor10145

See Also

1965 AHSC (ProblemsAnswer KeyResources)
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Problem 39
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