Complexity of Scott Sentences
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We give effective versions of some results on Scott sentences. We show that if $\mathcal{A}$ has a computable $\Pi_\alpha$ Scott sentence, then the orbits of all tuples are defined by formulas that are computable $\Sigma_\beta$ for some $\beta <\alpha$. (This is an effective version of a result of Montalb\'{a}n.) We show that if a countable structure $\mathcal{A}$ has a computable $\Sigma_\alpha$ Scott sentence and one that is computable $\Pi_\alpha$, then it has one that is computable $d$-$\Sigma_\beta$ for some $\beta < \alpha$. (This is an effective version of a result of A. Miller.) We also give an effective version of a result of D. Miller. Using the non-effective results of Montalb\'{a}n and A. Miller, we show that a finitely generated group has a $d$-$\Sigma_2$ Scott sentence iff the orbit of some (or every) generating tuple is defined by a $\Pi_1$ formula. Using our effective results, we show that for a computable finitely generated group, there is a computable $d$-$\Sigma_2$ Scott sentence iff the orbit of some (every) generating tuple is defined by a computable $\Pi_1$ formula.
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Scott complexity of trees of finite rank via degrees of categoricity
Computable trees of rank m+1 have Scott rank exactly 2m+1 with Scott sentence complexity in {Σ_{2m+1}, dΣ_{2m+1}, Π_{2m+2}}, and exactly Π_4 for rank 2.
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