In a paper of 1976, Rauzy studied two complexity notions, $\underline{β}$ and $\overline{β}$, for infinite sequences over a finite alphabet. The function $\underline{β}$ is maximum exactly in the Borel normal sequences and $\overline{β}$ is minimum exactly in the sequences that, when added to any Borel normal sequence, the result is also Borel normal. Although the definition of $\underline{β}$ and $\overline{β}$ do not involve finite-state automata, we establish some connections between them and the lower $\underline{\dim}$ and upper $\overline{\dim}$ finite-state dimension (or other equivalent notions like finite-state compression ratio, entropy or cumulative log-loss of finite-state predictors). We show tight lower and upper bounds on $\underline{\dim}$ and $\overline{\dim}$ as functions of $\underline{β}$ and $\overline{β}$, respectively. In particular this implies that sequences with $\overline{\dim}$ zero are exactly the ones that that, when added to any Borel normal sequence, the result is also Borel normal. We also show that the finite-state dimensions $\underline{\dim}$ and~$\overline{\dim}$ are essentially subadditive.