65 research outputs found
A Proof of the Factorization Forest Theorem
We show that for every homomorphism where is a finite
semigroup there exists a factorization forest of height \leq 3 \abs{S}. The
proof is based on Green's relations.Comment: 4 page
On Bijective Variants of the Burrows-Wheeler Transform
The sort transform (ST) is a modification of the Burrows-Wheeler transform
(BWT). Both transformations map an arbitrary word of length n to a pair
consisting of a word of length n and an index between 1 and n. The BWT sorts
all rotation conjugates of the input word, whereas the ST of order k only uses
the first k letters for sorting all such conjugates. If two conjugates start
with the same prefix of length k, then the indices of the rotations are used
for tie-breaking. Both transforms output the sequence of the last letters of
the sorted list and the index of the input within the sorted list. In this
paper, we discuss a bijective variant of the BWT (due to Scott), proving its
correctness and relations to other results due to Gessel and Reutenauer (1993)
and Crochemore, Desarmenien, and Perrin (2005). Further, we present a novel
bijective variant of the ST.Comment: 15 pages, presented at the Prague Stringology Conference 2009 (PSC
2009
Efficient Algorithms for Morphisms over Omega-Regular Languages
Morphisms to finite semigroups can be used for recognizing omega-regular
languages. The so-called strongly recognizing morphisms can be seen as a
deterministic computation model which provides minimal objects (known as the
syntactic morphism) and a trivial complementation procedure. We give a
quadratic-time algorithm for computing the syntactic morphism from any given
strongly recognizing morphism, thereby showing that minimization is easy as
well. In addition, we give algorithms for efficiently solving various decision
problems for weakly recognizing morphisms. Weakly recognizing morphism are
often smaller than their strongly recognizing counterparts. Finally, we
describe the language operations needed for converting formulas in monadic
second-order logic (MSO) into strongly recognizing morphisms, and we give some
experimental results.Comment: Full version of a paper accepted to FSTTCS 201
Fragments of first-order logic over infinite words
We give topological and algebraic characterizations as well as language
theoretic descriptions of the following subclasses of first-order logic FO[<]
for omega-languages: Sigma_2, FO^2, the intersection of FO^2 and Sigma_2, and
Delta_2 (and by duality Pi_2 and the intersection of FO^2 and Pi_2). These
descriptions extend the respective results for finite words. In particular, we
relate the above fragments to language classes of certain (unambiguous)
polynomials. An immediate consequence is the decidability of the membership
problem of these classes, but this was shown before by Wilke and Bojanczyk and
is therefore not our main focus. The paper is about the interplay of algebraic,
topological, and language theoretic properties.Comment: Conference version presented at 26th International Symposium on
Theoretical Aspects of Computer Science, STACS 200
Languages of Dot-depth One over Infinite Words
Over finite words, languages of dot-depth one are expressively complete for
alternation-free first-order logic. This fragment is also known as the Boolean
closure of existential first-order logic. Here, the atomic formulas comprise
order, successor, minimum, and maximum predicates. Knast (1983) has shown that
it is decidable whether a language has dot-depth one. We extend Knast's result
to infinite words. In particular, we describe the class of languages definable
in alternation-free first-order logic over infinite words, and we give an
effective characterization of this fragment. This characterization has two
components. The first component is identical to Knast's algebraic property for
finite words and the second component is a topological property, namely being a
Boolean combination of Cantor sets.
As an intermediate step we consider finite and infinite words simultaneously.
We then obtain the results for infinite words as well as for finite words as
special cases. In particular, we give a new proof of Knast's Theorem on
languages of dot-depth one over finite words.Comment: Presented at LICS 201
One Quantifier Alternation in First-Order Logic with Modular Predicates
Adding modular predicates yields a generalization of first-order logic FO
over words. The expressive power of FO[<,MOD] with order comparison and
predicates for has been investigated by Barrington,
Compton, Straubing and Therien. The study of FO[<,MOD]-fragments was initiated
by Chaubard, Pin and Straubing. More recently, Dartois and Paperman showed that
definability in the two-variable fragment FO2[<,MOD] is decidable. In this
paper we continue this line of work.
We give an effective algebraic characterization of the word languages in
Sigma2[<,MOD]. The fragment Sigma2 consists of first-order formulas in prenex
normal form with two blocks of quantifiers starting with an existential block.
In addition we show that Delta2[<,MOD], the largest subclass of Sigma2[<,MOD]
which is closed under negation, has the same expressive power as two-variable
logic FO2[<,MOD]. This generalizes the result FO2[<] = Delta2[<] of Therien and
Wilke to modular predicates. As a byproduct, we obtain another decidable
characterization of FO2[<,MOD]
The FO^2 alternation hierarchy is decidable
We consider the two-variable fragment FO^2[<] of first-order logic over
finite words. Numerous characterizations of this class are known. Th\'erien and
Wilke have shown that it is decidable whether a given regular language is
definable in FO^2[<]. From a practical point of view, as shown by Weis, FO^2[<]
is interesting since its satisfiability problem is in NP. Restricting the
number of quantifier alternations yields an infinite hierarchy inside the class
of FO^2[<]-definable languages. We show that each level of this hierarchy is
decidable. For this purpose, we relate each level of the hierarchy with a
decidable variety of finite monoids. Our result implies that there are many
different ways of climbing up the FO^2[<]-quantifier alternation hierarchy:
deterministic and co-deterministic products, Mal'cev products with definite and
reverse definite semigroups, iterated block products with J-trivial monoids,
and some inductively defined omega-term identities. A combinatorial tool in the
process of ascension is that of condensed rankers, a refinement of the rankers
of Weis and Immerman and the turtle programs of Schwentick, Th\'erien, and
Vollmer
Ehrenfeucht-Fraisse Games on Omega-Terms
Fragments of first-order logic over words can often be characterized in terms
of finite monoids or finite semigroups. Usually these algebraic descriptions
yield decidability of the question whether a given regular language is
definable in a particular fragment. An effective algebraic characterization can
be obtained from identities of so-called omega-terms. In order to show that a
given fragment satisfies some identity of omega-terms, one can use
Ehrenfeucht-Fraisse games on word instances of the omega-terms. The resulting
proofs often require a significant amount of book-keeping with respect to the
constants involved. In this paper we introduce Ehrenfeucht-Fraisse games on
omega-terms. To this end we assign a labeled linear order to every omega-term.
Our main theorem shows that a given fragment satisfies some identity of
omega-terms if and only if Duplicator has a winning strategy for the game on
the resulting linear orders. This allows to avoid the book-keeping. As an
application of our main result, we show that one can decide in exponential time
whether all aperiodic monoids satisfy some given identity of omega-terms,
thereby improving a result of McCammond (Int. J. Algebra Comput., 2001)
Star-free languages and local divisors
A celebrated result of Schützenberger says that a language is star-free if and only if it is is recognized by a finite aperiodic monoid. We give a new proof for this theorem using local divisors. © 2014 Springer International Publishing
Solutions of Word Equations over Partially Commutative Structures
We give NSPACE(n log n) algorithms solving the following decision problems.
Satisfiability: Is the given equation over a free partially commutative monoid
with involution (resp. a free partially commutative group) solvable?
Finiteness: Are there only finitely many solutions of such an equation? PSPACE
algorithms with worse complexities for the first problem are known, but so far,
a PSPACE algorithm for the second problem was out of reach. Our results are
much stronger: Given such an equation, its solutions form an EDT0L language
effectively representable in NSPACE(n log n). In particular, we give an
effective description of the set of all solutions for equations with
constraints in free partially commutative monoids and groups
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