# 2013 AMC 12A Problems/Problem 21

## Solution

Let $f(x) = \log(x + f(x-1))$ and $f(2) = log(2)$, and from the problem description, $A = f(2013)$

We can reason out an approximation, by ignoring the $f(x-1)$: $f(x) \approx \log x$

And a better approximation, by plugging in our first approximation for $f(x-1)$ in our original definition for $f(x)$: $f(x) \approx \log(x + \log(x-1))$

And an even better approximation: $f(x) \approx \log(x + \log(x-1 + \log(x-2)))$

Continuing this pattern, obviously, will eventually terminate at our original definition of $f(x)$.

However, at $x = 2013$, going further than our second approximation will not distinguish between our answer choices.

So we take our second approximation and plug in. $f(2013) \approx \log(2013 + \log 2012)$

Since $1000 < 2012 < 10000$, we know $3 < log(2012) < 4$. This gives us our answer range: $\log 2016 < \log(2013 + \log 2012) < \log(2017)$ $(\log 2016, \log 2017)$

## Solution 2

We see that $10^A = 2013 + \cdots$, and that the quantity within " $\cdots$" is between $\log(1000)$ and $\log(10000)$, i.e. $(3,4)$, therefore $10^A \in (2016,2017)$, or $A\in (\log(2016),\log(2017))$.