I should start with the following disclaimer that I know virtually no logic, sorry forgive me if my questions are ill-posed. I appreciate that all of this is probably completely obvious to a logician, but I've gone round asking all these to a lot of mathematicians around me and have so far failed to get any sort of satisfactory answer/reference on the topic.
I'm going to start with a pair of formal questions, and then explain where these come from.
- Could it be that the statement "$\pi$ is a disjunctive number" is undecidable?
- Could it be that the statement "The circle diffeomorphism $x \mapsto x + \sqrt{2} + 0.1 \sin(2\pi x)$ has irrational rotation number" is undecidable?
(One more disclaimer, I don't know the formal definition of the concept of undecidability. I take it that a statement is undecidable if assuming that it is true or false in a coherent logical system doesn't create any incoherence).
Undecidability and unprovable statements Like many people I suppose, I've always regarded the question of undecidability as a fairly esoteric one which I shouldn't concern myself with, as it is unlikely I ever come across an undecidable statement. This is mostly because the only example of undecidable I knew about was the continuum hypothesis, and until I'd come across a concrete, reasonable set whose cardinality couldn't be established it would always feel like an empty statement.
Now it's come to my attention that there could be statements which are true but that one couldn't prove. For instance, you could imagine two somewhat explicit functions $f,g : \mathbb{N} \longrightarrow \mathbb{N}$ such that the statement $\forall n, f(n) > g(n)$ is undecidable. That's where my understanding of logic becomes too shaky, but I can't imagine a statement of this form not being, for any reasonable definition of the concepts, either true or false. For all $n$, I can check whether it is true. So if it were to be false, I could exhibit a particular $n$ for which $f(n) \leq g(n)$.
If the statement is undecidable, it's just that it can't be proved.
Now (sorry if it's getting too philosophical), most statements that we try to prove we have reasons to think that they are true; a proof is not just a formal logical reasoning, it's also taming some sort of phenomenon which we thought was behind the statement.
There could well be some (simple) statements, which turn out to be true for no particular phenomenological reason. Such statements, I would actually be surprised if they could be proven to be true, as in my semi-religious belief a proof is a phenomenological justification for why something is true. It's bumping into such a statement (the second one above) that I started wondering about this kind of things.
The rotation number as a potential source of undecidability For those who do not know much dynamical systems, to a circle homeomorphism $T : S^1 \longrightarrow S^1$, one can associate a number $\rho(T) \in S^1 = \mathbb{R}/\mathbb{Z}$ which has some dynamical significance. It's a well-known theorem that in parameter families like $T_{\alpha, \epsilon} := x \mapsto x + \alpha + \epsilon \sin(2 \pi x)$, the probability that a parameter $(\alpha, \epsilon)$ corresponds to a rational/irrational rotation number has positive probability.
The definition of the rotation number involves taking a limit of infinitely many iterations of the map $T$, and somehow is highly transcendental with respect to the parameters $(\alpha, \epsilon)$. I want to speculate that the precise value of $(\alpha, \epsilon)$ is somewhat uncorrelated to the actual dynamical behaviour of $T_{\alpha, \epsilon}$. If there were a proof that $x \mapsto x + \sqrt{2} + 0.1 \sin(2\pi x)$ has irrational or rational rotation number, it would suggest that arithmetic properties of $\alpha$ and $\epsilon$ are reflected in the highly transcendental process of taking a limit of many iterations of $T_{\alpha, \epsilon}$. I would find this hard to believe, and therefore I would incline to believe that such a statement cannot be proven!
$\pi$ is disjunctive A number is disjunctive if its decimal expansion contains every finite sequence. It is relatively easy to prove that almost every real number is disjunctive. But now if one takes a number which is not defined in terms of its decimal expansion and that its decimal expansion cannot be made somewhat explicit using the (a) way it is defined, I would expect that
- it is disjunctive (because almost every number is)
- it is impossible to prove if the way the number is defined is "transcendental with respect to the decimal expansion".
Are such statements undecidable? The more I do maths, the more I come across conjectures about particular objects, the heuristical reasons why they are believed to be true seem to be true only generically for a wider class of objects. Has anyone considered the fact that such statements could be very good candidates for being undecidable statements?
A general question to conclude would then be : do logicians have interesting things to say about problems with this general structure? (a statement $S$ about a particular object $A$, known to hold true only generically for a wider class of objects $\mathcal{C}$, the definition of $A$ being "transcendental" with respect to the properties used in the proof that generic objects of $\mathcal{C}$ satisfy $S$).
