A Divergence Formula for Randomness and Dimension

Abstract

If S is an infinite sequence over a finite alphabet and β is a probability measure on , then the dimension of S with respect to β, written β(S), is a constructive version of Billingsley dimension that coincides with the (constructive Hausdorff) dimension (S) when β is the uniform probability measure. This paper shows that β(S) and its dual β(S), the strong dimension of S with respect to β, can be used in conjunction with randomness to measure the similarity of two probability measures α and β on . Specifically, we prove that the divergence formula \[ β(R) = β(R) =(α)(α) + (α || β) \] holds whenever α and β are computable, positive probability measures on and R ∈ ∞ is random with respect to α. In this formula, (α) is the Shannon entropy of α, and (α||β) is the Kullback-Leibler divergence between α and β. We also show that the above formula holds for all sequences R that are α-normal (in the sense of Borel) when β(R) and β(R) are replaced by the more effective finite-state dimensions β(R) and β(R). In the course of proving this, we also prove finite-state compression characterizations of β(S) and β(S).