A Generalization of the Łoś-Tarski Preservation Theorem (1609.06297v1)

Abstract: In this dissertation, we present for each natural number $k$, semantic characterizations of the $\exists^k \forall^*$ and $\forall^k \exists^*$ prefix classes of first order logic sentences, over all structures finite and infinite. This result, that we call the generalized {\L}o\'s-Tarski theorem, abbreviated $\mathsf{GLT}(k)$, yields the classical {\L}o\'s-Tarski preservation theorem when $k$ equals 0. It also provides new characterizations of the $\Sigma^0_2$ and $\Pi^0_2$ prefix classes, that are finer than all characterizations of these classes in the literature. Further, our semantic notions are finitary in nature, in contrast to those contained in the literature characterizations. In the context of finite structures, we formulate an abstract combinatorial property of structures, that when satisfied by a class, ensures that $\mathsf{GLT}(k)$ holds over the class. This property, that we call the Equivalent Bounded Substructure Property, abbreviated $\mathsf{EBSP}$, intuitively states that a large structure contains a small "logically similar" substructure. It turns out that this simply stated property is enjoyed by a variety of classes of interest in computer science: examples include words, trees (unordered, ordered or ranked), nested words, graph classes of bounded tree-depth/shrub-depth, and $m$-partite cographs. Further, $\mathsf{EBSP}$ remains preserved under various well-studied operations, such as complementation, transpose, the line-graph operation, disjoint union, cartesian and tensor products, etc. This enables constructing a wide spectrum of classes that satisfy $\mathsf{EBSP}$, and hence $\mathsf{GLT}(k)$. Remarkably, $\mathsf{EBSP}$ can be regarded as a finitary analogue of the classical downward L\"owenheim-Skolem property. In summary, this dissertation provides new notions and results in both contexts, that of all structures and that of finite structures.