Dimension of graphoids of rational vector-functions

Abstract

Let F be a countable family of rational functions of two variables with real coefficients. Each rational function f∈ F can be thought as a continuous function f:dom(f) R taking values in the projective line R=R\∞\ and defined on a cofinite subset dom(f) of the torus R2. Then the family determines a continuous vector-function F:dom(F) RF defined on the dense Gδ-set dom(F)=f∈ Fdom(F) of R2. The closure (F) of its graph (F)=\(x,f(x)):x∈ dom(F)\ in R2× RF is called the graphoid of the family F. We prove the graphoid (F) has topological dimension dim((F))=2. If the family F contains all linear fractional transformations f(x,y)=x-ay-b for (a,b)∈ Q2, then the graphoid (F) has cohomological dimension dimG((F))=1 for any non-trivial 2-divisible abelian group G. Hence the space (F) is a natural example of a compact space that is not dimensionally full-valued and by this property resembles the famous Pontryagin surface.