Monadic Second-Order Logic of Permutations
Abstract
Permutations can be viewed as pairs of linear orders, or more formally as models over a signature consisting of two binary relation symbols. This approach was adopted by Albert, Bouvel and F\'eray, who studied the expressibility of first-order logic in this setting. We focus our attention on monadic second-order logic. Our results go in two directions. First, we investigate the expressive power of monadic second-order logic. We exhibit natural properties of permutations that can be expressed in monadic second-order logic but not in first-order logic. Additionally, we show that the property of having a fixed point is inexpressible even in monadic second-order logic. Secondly, we focus on the complexity of monadic second-order model checking. We show that there is an algorithm deciding if a permutation π satisfies a given monadic second-order sentence in time f(||, tw(π)) · n for some computable function f where n = |π| and tw(π) is the tree-width of π. On the other hand, we prove that the problem remains hard even when we restrict the permutation π to a fixed hereditary class C with mild assumptions on C.
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