(p,q)-adic Analysis and the Collatz Conjecture
Abstract
What use can there be for a function from the p-adic numbers to the q-adic numbers, where p and q are distinct primes? The traditional answer, courtesy of the half-century old theory of non-archimedean functional analysis: not much. It turns out this judgment was premature. '(p,q)-adic analysis' of this sort appears to be naturally suited for studying the infamous Collatz map and similar arithmetical dynamical systems. Given such a map H:Z→Z, one can construct a function H:Zp→Zq for an appropriate choice of distinct primes p,q with the property that x∈Z\ 0\ is a periodic point of H if and only if there is a p-adic integer z∈(Qp)\ 0,1,2,…\ so that H(z)=x. By generalizing Monna-Springer integration theory and establishing a (p,q)-adic analogue of the Wiener Tauberian Theorem, one can show that the question 'is x∈Z\ 0\ a periodic point of H?' is essentially equivalent to 'is the span of the translates of the Fourier transform of H(z)-x dense in an appropriate non-archimedean function space?' This presents an exciting new frontier in Collatz research, and these methods can be used to study Collatz-type dynamical systems on the lattice Zd for any d≥1.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.