Expressive Power of Monadic Second-Order Logic and Modal μ-Calculus

AbstractThis paper studies the expressive power that an extra first order quantifier adds to a fragment of monadic second order logic, extending the toolkit of Janin and Marcinkowski [JM01].We introduce an operation existsn (S) on properties S that says “there are n components having S”. We use this operation to show that under natural strictness conditions, adding a first order quantifier word u to the beginning of a prefix class V increases the expressive power monotonically in u. As a corollary, if the first order quantifiers are not already absorbed in V, then both the quantifier alternation hierarchy and the existential quantifier hierarchy in the positive first order closure of V are strict.We generalize and simplify methods from Marcinkowski [Mar99] to uncover limitations of the expressive power of an additional first order quantifier, and show that for a wide class of properties S, S cannot belong to the positive first order closure of a monadic prefix class W unless it already belongs to W.We introduce another operation alt(S) on properties which has the same relationship with the Circuit Value Problem as reach(S) (defined in [JM01]) has with the Directed Reachability Problem. We use alt(S) to show that Πn ⊈ FO(Σn), Σn ⊈ FO(∆n). and ∆n+1 ⊈ FOB(Σn), solving some open problems raised in [Mat98].

Download Full-text

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

Discrete Mathematics & Theoretical Computer Science ◽

10.46298/dmtcs.254 ◽

1999 ◽

Vol Vol. 3 no. 3 ◽

Author(s):

Thomas Schwentick ◽

Klaus Barthelmann

Keyword(s):

Normal Forms ◽

Winning Strategy ◽

Expressive Power ◽

Second Order ◽

Order Logic ◽

First Order Logic ◽

First Order ◽

Relational Structures ◽

Second Order Logic ◽

Monadic Second Order Logic

International audience 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 models are defined that have, on arbitrary classes of relational structures, exactly the expressive power of first-order logic and existential monadic second-order logic, respectively.

Download Full-text

Expanding the Expressive Power of Monadic Second-Order Logic on Restricted Graph Classes

Lecture Notes in Computer Science - Combinatorial Algorithms ◽

10.1007/978-3-642-45278-9_15 ◽

2013 ◽

pp. 164-177 ◽

Cited By ~ 3

Author(s):

Robert Ganian ◽

Jan Obdržálek

Keyword(s):

Expressive Power ◽

Second Order ◽

Order Logic ◽

Graph Classes ◽

Second Order Logic ◽

Monadic Second Order Logic

Download Full-text

Monadic second-order logic on finite sequences

Proceedings of the 44th ACM SIGPLAN Symposium on Principles of Programming Languages - POPL 2017 ◽

10.1145/3009837.3009844 ◽

2017 ◽

Cited By ~ 4

Author(s):

Loris D'Antoni ◽

Margus Veanes

Keyword(s):

Second Order ◽

Order Logic ◽

Finite Sequences ◽

Second Order Logic ◽

Monadic Second Order Logic

Download Full-text

The Complexity of Model-Checking Tail-Recursive Higher-Order Fixpoint Logic

Fundamenta Informaticae ◽

10.3233/fi-2021-1996 ◽

2021 ◽

Vol 178 (1-2) ◽

pp. 1-30

Author(s):

Florian Bruse ◽

Martin Lange ◽

Etienne Lozes

Keyword(s):

Model Checking ◽

Lower Bounds ◽

Expressive Power ◽

Higher Order ◽

Order Logic ◽

High Complexity ◽

Transition Systems ◽

Recursive Formulas ◽

Second Order Logic ◽

Monadic Second Order Logic

Higher-Order Fixpoint Logic (HFL) is a modal specification language whose expressive power reaches far beyond that of Monadic Second-Order Logic, achieved through an incorporation of a typed λ-calculus into the modal μ-calculus. Its model checking problem on finite transition systems is decidable, albeit of high complexity, namely k-EXPTIME-complete for formulas that use functions of type order at most k < 0. In this paper we present a fragment with a presumably easier model checking problem. We show that so-called tail-recursive formulas of type order k can be model checked in (k − 1)-EXPSPACE, and also give matching lower bounds. This yields generic results for the complexity of bisimulation-invariant non-regular properties, as these can typically be defined in HFL.

Download Full-text