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We can call the $x$th Fibonacci number Fib($x$). What's the best asymptotic lower bounds on the amount of relatively prime Fibonacci numbers between Fib($n$) and Fib($n+m$)?

In other words, if we take the $m$ Fibonacci numbers that lie between Fib($n$) (inclusive) and Fib($n+m$), what is the maximally sized set of these numbers can be pairwise relatively prime to each other, in terms of $n$ and $m$? Of course, I'm looking for some sort of asymptotic bounds - more specifically, a big Omega bound, but we are allowed to pick from any of the $m$ Fibonacci numbers in the sequence, in order to make this bound larger. Note that I'm looking for the maximally sized set, but in the worst case.

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    $\begingroup$ Relatively prime to what? To each other? What is the maximally sized set of Fibonacci numbers in that range that are all pairwise relatively prime? Is that the question? $\endgroup$ – Zubin Mukerjee Oct 2 '18 at 19:04
  • $\begingroup$ @ZubinMukerjee: Yes, relatively prime to each other, and yes, the maximally sized set that are all pairwise relatively prime - thank you! $\endgroup$ – Matt Groff Oct 2 '18 at 19:05
  • $\begingroup$ Note that every third Fib(n) is even, every fourth is divisible by $3$, every fifth by $5$, and that in general every $d^{th}$ is divisible by Fib(d). If indices are coprime so are the Fibonacci numbers (at least with Fib$(1)=1$, Fib$(2)=1$) So this becomes essentially the same problem as picking coprime integers for the indices. $\endgroup$ – Mark Bennet Oct 2 '18 at 20:04
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Although this appears to be intrinsically a question about Fibonacci numbers, in fact the Fibonacci numbers are a guise. The key aspect to notice here is that $$ \gcd(Fib(n), Fib(m)) = Fib(\gcd(n,m)).$$ (This is proved, for instance, in this other post on this site).

Thus $Fib(n)$ and $Fib(m)$ are relatively prime exactly when $\gcd(m,n) = 1$ or $2$. Your question is now a question about relatively prime (or divisible by exactly $2$) sets of numbers.

The relevant question to ask is the following.

What is the size of the largest subset $S \subseteq [m, n]$ such that $x,y \in S$ implies that $\gcd(x,y) = 1$ or $\gcd(x,y) = 2$?

A clear lower bound is the number of primes between $m$ and $n$, $\pi(n) - \pi(m)$. In fact, one can also use numbers which are twice a prime, so a slightly better lower bound is $\pi(n) - \pi(m/2)$. Asymptotically, if $n - m = X$, then this guarantees $X / \log X$ as a lower bound.

It is not clear to me how much better you can actually do. This seems to me to be a nice, hard problem --- precisely the sort of thing that Erdos or Pomerance would be interested in.

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  • $\begingroup$ I upvoted and will probably accept your nice answer. Just a comment... From this answer and comments: math.stackexchange.com/a/1816646/2626 See the comments below... We can pick a set of primes $p_k$ that are small, and then use the GCD $g$ of all pairwise differences of the primes to get small Fibonacci's $g+p_k$. I doubt this will be the best bound in most cases, but it seems to me to give a reasonable set of Fibonacci numbers. Anyways, thanks for your nice answer, and maybe some Erdos or Pomerance will come along and help! $\endgroup$ – Matt Groff Oct 3 '18 at 15:37

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