602 research outputs found
An effective characterization of the alternation hierarchy in two-variable logic
We characterize the languages in the individual levels of the quantifier
alternation hierarchy of first-order logic with two variables by identities.
This implies decidability of the individual levels. More generally we show that
the two-sided semidirect product of a decidable variety with the variety J is
decidable
A Team Based Variant of CTL
We introduce two variants of computation tree logic CTL based on team
semantics: an asynchronous one and a synchronous one. For both variants we
investigate the computational complexity of the satisfiability as well as the
model checking problem. The satisfiability problem is shown to be
EXPTIME-complete. Here it does not matter which of the two semantics are
considered. For model checking we prove a PSPACE-completeness for the
synchronous case, and show P-completeness for the asynchronous case.
Furthermore we prove several interesting fundamental properties of both
semantics.Comment: TIME 2015 conference version, modified title and motiviatio
The model checking fingerprints of CTL operators
The aim of this study is to understand the inherent expressive power of CTL
operators. We investigate the complexity of model checking for all CTL
fragments with one CTL operator and arbitrary Boolean operators. This gives us
a fingerprint of each CTL operator. The comparison between the fingerprints
yields a hierarchy of the operators that mirrors their strength with respect to
model checking
Two-variable logics with some betweenness relations: Expressiveness, satisfiability and membership
We study two extensions of FO2[<], first-order logic interpreted in finite
words, in which formulas are restricted to use only two variables. We adjoin to
this language two-variable atomic formulas that say, "the letter appears
between positions and " and "the factor appears between positions
and ". These are, in a sense, the simplest properties that are not
expressible using only two variables.
We present several logics, both first-order and temporal, that have the same
expressive power, and find matching lower and upper bounds for the complexity
of satisfiability for each of these formulations. We give effective conditions,
in terms of the syntactic monoid of a regular language, for a property to be
expressible in these logics. This algebraic analysis allows us to prove, among
other things, that our new logics have strictly less expressive power than full
first-order logic FO[<]. Our proofs required the development of novel
techniques concerning factorizations of words
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