Search results for "Monadic second-order logic"

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Local Normal Forms for First-Order Logic with Applications to Games and Automata

1999

Building on work of Gaifman [Gai82] it is shown that every first-order formula is logically equivalent to a formula of the form ∃ x_1,...,x_l, \forall y, φ where φ is r-local around y, i.e. quantification in φ is restricted to elements of the universe of distance at most r from y. \par From this and related normal forms, variants of the Ehrenfeucht game for first-order and existential monadic second-order logic are developed that restrict the possible strategies for the spoiler, one of the two players. This makes proofs of the existence of a winning strategy for the duplicator, the other player, easier and can thus simplify inexpressibility proofs. \par As another application, automata mode…

General Computer ScienceLogical equivalenceautomataComputer scienceOf the formMathematical proofMonadic predicate calculusTheoretical Computer ScienceCombinatoricslocalityDeterministic automatonDiscrete Mathematics and CombinatoricsMathematicsgamesDiscrete mathematicsPredicate logiclcsh:MathematicsLocalityAtomic formulaexistential monadic second-order logiclcsh:QA1-939AutomatonFirst-order logic[INFO.INFO-DM] Computer Science [cs]/Discrete Mathematics [cs.DM]TheoryofComputation_MATHEMATICALLOGICANDFORMALLANGUAGESAutomata theoryFirst-order logicDiscrete Mathematics & Theoretical Computer Science
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Monadic Second-Order Logic over Rectangular Pictures and Recognizability by Tiling Systems

1996

Abstract It is shown that a set of pictures (rectangular arrays of symbols) is recognized by a finite tiling system iff it is definable in existential monadic second-order logic. As a consequence, finite tiling systems constitute a notion of recognizability over two-dimensional inputs which at the same time generalizes finite-state recognizability over strings and also matches a natural logic. The proof is based on the Ehrenfeucht–Fraisse technique for first-order logic and an implementation of “threshold counting” within tiling systems.

Predicate logicMonadic second-order logicDiscrete mathematicsNatural logicIntermediate logicHigher-order logicMonadic predicate calculusComputer Science ApplicationsTheoretical Computer ScienceMathematics::LogicTheoryofComputation_MATHEMATICALLOGICANDFORMALLANGUAGESComputational Theory and MathematicsComputer Science::Logic in Computer ScienceMany-valued logicDynamic logic (modal logic)Computer Science::Formal Languages and Automata TheoryInformation SystemsMathematicsInformation and Computation
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