2017 AMC 12A Problems/Problem 20

Problem

How many ordered pairs $(a,b)$ such that $a$ is a positive real number and $b$ is an integer between $2$ and $200$ , inclusive, satisfy the equation $(log_b a)^{2017}=log_b(a^{2017})?$

$\textbf{(A)}\ 198\qquad\textbf{(B)}\ 199\qquad\textbf{(C)}\ 398\qquad\textbf{(D)}\ 399\qquad\textbf{(E)}\ 597$

Solution

By the properties of logarithms, we can rearrange the equation to read $2017 log_b a=(log_b a)^{2017}$ . Then, subtracting $2017log_b a$ from each side yields $(log_b a)^{2017}-2017log_b a=0$ . We then proceed to factor out the term $log_b a$ which results in $(log_b a)[(log_b a)2016-2017]=0$ . Then, we set both factors equal to zero and solve.

$log_b a=0$ has exactly $199$ solutions with the restricted domain of $[2,200]$ since this equation will always have a solution in the form of $(1, b)$ , and there are $199$ possible values of $b$ since $200-2+1 = 199$ .

We proceed to solve the other factor, $(log_b a)2016-2017$ . We add $2017$ to both sides, and take the $2016th$ root, this gives us $log_b a=\sqrt[2016]{2017}$ $\sqrt[2016]{2017}$ is a real number, and therefore $a=b^{\sqrt[2016]{2017}}$ Again, there are $199$ solutions, as $b^{\sqrt[2016]{2017}}$ must be a real number (It's a real number raised to a real number).

Therefore, there are as many solutions as possible $b$ values, and as there is only one value of a for each $b$ , $199 + 199 = 398$ , therefore the answer is $\textbf{D}$ .

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2017 AMC 12A Problems/Problem 20

Problem

Solution