Your search keyword '"03B70, 68Q45"' showing total 3 results

1. Ambiguity Hierarchy of Regular Infinite Tree Languages

Author

Rabinovich, Alexander and Tiferet, Doron

Subjects

Computer Science - Logic in Computer Science, Computer Science - Computation and Language, 03B70, 68Q45, F.4.3

Abstract

An automaton is unambiguous if for every input it has at most one accepting computation. An automaton is k-ambiguous (for k > 0) if for every input it has at most k accepting computations. An automaton is boundedly ambiguous if it is k-ambiguous for some $k \in \mathbb{N}$. An automaton is finitely (respectively, countably) ambiguous if for every input it has at most finitely (respectively, countably) many accepting computations. The degree of ambiguity of a regular language is defined in a natural way. A language is k-ambiguous (respectively, boundedly, finitely, countably ambiguous) if it is accepted by a k-ambiguous (respectively, boundedly, finitely, countably ambiguous) automaton. Over finite words every regular language is accepted by a deterministic automaton. Over finite trees every regular language is accepted by an unambiguous automaton. Over $\omega$-words every regular language is accepted by an unambiguous B\"uchi automaton and by a deterministic parity automaton. Over infinite trees Carayol et al. showed that there are ambiguous languages. We show that over infinite trees there is a hierarchy of degrees of ambiguity: For every k > 1 there are k-ambiguous languages that are not k - 1 ambiguous; and there are finitely (respectively countably, uncountably) ambiguous languages that are not boundedly (respectively finitely, countably) ambiguous.

Published

2020

2. Ambiguity Hierarchy of Regular Infinite Tree Languages

Author

Alexander Rabinovich and Doron Tiferet

Subjects

computer science - logic in computer science, computer science - computation and language, 03b70, 68q45, f.4.3, Logic, BC1-199, Electronic computers. Computer science, QA75.5-76.95

Abstract

An automaton is unambiguous if for every input it has at most one accepting computation. An automaton is k-ambiguous (for k > 0) if for every input it has at most k accepting computations. An automaton is boundedly ambiguous if it is k-ambiguous for some $k \in \mathbb{N}$. An automaton is finitely (respectively, countably) ambiguous if for every input it has at most finitely (respectively, countably) many accepting computations. The degree of ambiguity of a regular language is defined in a natural way. A language is k-ambiguous (respectively, boundedly, finitely, countably ambiguous) if it is accepted by a k-ambiguous (respectively, boundedly, finitely, countably ambiguous) automaton. Over finite words every regular language is accepted by a deterministic automaton. Over finite trees every regular language is accepted by an unambiguous automaton. Over $\omega$-words every regular language is accepted by an unambiguous B\"uchi automaton and by a deterministic parity automaton. Over infinite trees Carayol et al. showed that there are ambiguous languages. We show that over infinite trees there is a hierarchy of degrees of ambiguity: For every k > 1 there are k-ambiguous languages that are not k - 1 ambiguous; and there are finitely (respectively countably, uncountably) ambiguous languages that are not boundedly (respectively finitely, countably) ambiguous.

Published

2021

3. Ambiguity Hierarchy of Regular Infinite Tree Languages

Author

Doron Tiferet and Alexander Rabinovich

Subjects

FOS: Computer and information sciences, Computer Science - Logic in Computer Science, General Computer Science, media_common.quotation_subject, Büchi automaton, Theoretical Computer Science, Regular language, Deterministic automaton, Mathematics, media_common, Discrete mathematics, ambiguous automata, 03B70, 68Q45, Theory of computation → Automata over infinite objects, Computer Science - Computation and Language, Degree (graph theory), Hierarchy (mathematics), monadic second-order logic, Computer Science::Computation and Language (Computational Linguistics and Natural Language and Speech Processing), Ambiguity, Nonlinear Sciences::Cellular Automata and Lattice Gases, Automaton, Logic in Computer Science (cs.LO), automata on infinite trees, F.4.3, Tree (set theory), Computation and Language (cs.CL), Computer Science::Formal Languages and Automata Theory

Abstract

An automaton is unambiguous if for every input it has at most one accepting computation. An automaton is k-ambiguous (for k > 0) if for every input it has at most k accepting computations. An automaton is boundedly ambiguous if there is k ∈ ℕ, such that for every input it has at most k accepting computations. An automaton is finitely (respectively, countably) ambiguous if for every input it has at most finitely (respectively, countably) many accepting computations. The degree of ambiguity of a regular language is defined in a natural way. A language is k-ambiguous (respectively, boundedly, finitely, countably ambiguous) if it is accepted by a k-ambiguous (respectively, boundedly, finitely, countably ambiguous) automaton. Over finite words every regular language is accepted by a deterministic automaton. Over finite trees every regular language is accepted by an unambiguous automaton. Over ω-words every regular language is accepted by an unambiguous Büchi automaton [Arnold, 1983] and by a deterministic parity automaton. Over infinite trees there are ambiguous languages [Carayol et al., 2010]. We show that over infinite trees there is a hierarchy of degrees of ambiguity: For every k > 1 there are k-ambiguous languages which are not k-1 ambiguous; there are finitely (respectively countably, uncountably) ambiguous languages which are not boundedly (respectively finitely, countably) ambiguous.

Published

2020