Growth of the size of iterated polynomials

Question

I have been working independently on a project but now I am stuck and need to seek an expert's wisdom for a part of it. I am basically looking for theorems related to growth of the size of polynomials. My Google search has led me to papers on root-finding algorithms which is not what I intend to do.

I am dealing with polynomials $p(x)$ of degree at least $2$ in $\mathbb{Z}[x]$ with a non-zero constant term and the size of the $n$-th iteration, i.e. $|p^{\circ n}(a)|$, where $a$ is any integer.

My example was very specific but I am looking for anything remotely similar. Is there any results that you know of related to the size and the growth rate of polynomials? Any comparison or upper/lower bound theorems?

Answer 1

The quantity you're looking for, I think, is the canonical height of $a$ with respect to the polynomial $p(x)$. In your situation, since you're just dealing with integers, if we let $d=\deg(p)\ge 2$, then the canonical height is defined by $$ \hat h_p(a) = \lim_{n\to\infty} \frac{1}{d^n}\log\bigl|p^n(a)\bigr|. $$ The fact that the limit converges is due to Tate, and a very general version was proven by Call and me. The canonical height has many nice properties, including the following:

• There is a constant $C=C(p)$ so $\bigl|\hat h_p(b) - \log|b|\bigr|<C$ for all integers $b$.
• $\hat h_p\bigl(p(b)\bigr) = d \hat h_p(b)$ for all integers $b$.
• The integer $b$ is preperiodic for $p$ if and only if $\hat h_p(b)=0$. (Being preperiodic means that there are $m>n\ge0$ so that $p^m(b)=p^n(b)$. Note that in any case we have $\hat h_p(b)\ge0$.)

In particular, if your $a$ is not preperiodic, then using these facts you get a pretty good estimate for $\log\bigl|p^n(a)\bigr|$, namely $$ \log\bigl|p^n(a)\bigr| = \hat h_p\bigl(p^n(a)\bigr) + O(1) = d^n \hat h_p(a) + O(1), $$ where the $O(1)$ depends on $p$, but not on $a$ or $n$. Further, with more work, one can even show that if $B$ is a bound for the largest coefficient of $p(x)$, then the $O(1)$ can be replaced by $O(\log|B|)$, where now the big-$O$ constant depends only on the degree of $p(x)$. Here are a couple references for all of this:

Section 3.4 of The Arithmetic of Dynamical Systems, J.H. Silverman, Springer, GTM 241.

G. Call, J.H. Silverman, Canonical heights on varieties with morphisms, Compositio Math. 89 (1993), 163-205.

Answer 2

The size of $|p^n(a)|$ can be very different depending on $a$. If $a$ is periodic point of $p$, then this sequence will be bounded. If $a$ is in the domain of attraction of infinity then $\log|p^n(a)|$ is like $d^n$ where $d$ is the degree.

More precisely, for each polynomial there is a compact set $K(p)$ in the complex plane, called the filled in Julia set, such that for $a\in K(f)$ your sequence is bounded, while for $a\not\in K(p)$ it grows like $d^n$. When searching on Google look on "Holomorphic dynamics".

Remark. It is irrelevant for what I wrote above, whether $a$ is an integer or not and whether the coefficients are integer or complex. However, as Joe Silverman suggested in his comment, if the coefficients and $a$ are integers, then $p^n(a)$ are also integers, and as $K(f)$ may contain only finitely many integers, the sequence can be bounded only if it is pre-periodic, that is becomes periodic after the removal of finitely many terms.

EDIT. So for polynomials over integers and integer $a$, the question whether the sequence is bounded can be solved by finitely many arithmetic operations. But this is not completely trivial: one needs an explicit estimate, how many integer points can $K(f)$ contain, or something equivalent to this.

And from the discussion of the history I conclude that the result essentially follows from a theorem of L. E. Bottcher (early 1900-s) who proved the existence of an analytic function $\phi(z)\sim z$ near $\infty$ which conjugates the polynomial with $z^d$, that is $$\phi\circ p(z)=\phi(z)^d.$$ But Bottcher did not investigate the full domain of existence of this function, and $\phi$ may not exist in the whole domain of attraction of $\infty$. The idea to consider $\log|\phi|$ which is well-defined in the whole domain of attraction and can be extended to a subharmonic function in the whole plane was for the first time published by Brolin in 1965. Tate apparently had the same idea simultaneously or earlier but did not publish it.