On the Cantor and Hilbert Cube Frames and the Alexandroff-Hausdorff Theorem

Abstract

The aim of this work is to give a pointfree description of the Cantor set. It can be shown that the Cantor set is homeomorphic to the p-adic integers Zp:=\x∈Qp: |x|p≤ 1\ for every prime number p. To give a pointfree description of the Cantor set, we specify the frame of Zp by generators and relations. We use the fact that the open balls centered at integers generate the open subsets of Zp and thus we think of them as the basic generators; on this poset we impose some relations and then the resulting quotient is the frame of the Cantor set L(Zp). We prove that L(Zp) is a spatial frame whose space of points is homeomorphic to Zp. In particular, we show with pointfree arguments that L(Zp) is 0-dimensional, (completely) regular, compact, and metrizable (it admits a countably generated uniformity). Finally, we give a point-free counterpart of the Hausdorff-Alexandroff Theorem which states that every compact metric space is a continuous image of the Cantor space (see, e.g. Alexandroff and Hausdorff). We prove the point-free analog: if L is a compact metrizable frame, then there is an injective frame homomorphism from L into L(Z2).