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Natural Computing

Erschienen in:

01.03.2016

More on quantum, stochastic, and pseudo stochastic languages with few states

verfasst von: Arseny M. Shur, Abuzer Yakaryılmaz

Erschienen in: Natural Computing | Ausgabe 1/2016

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Abstract

Stochastic languages are the languages recognized by probabilistic finite automata (PFAs) with cutpoint over the field of real numbers. More general computational models over the same field such as generalized finite automata (GFAs) and quantum finite automata (QFAs) define the same class. In 1963, Rabin proved the set of stochastic languages to be uncountable presenting a single 2-state PFA over the binary alphabet recognizing uncountably many languages depending on the cutpoint. In this paper, we show the same result for unary stochastic languages. Namely, we exhibit a 2-state unary GFA, a 2-state unary QFA, and a family of 3-state unary PFAs recognizing uncountably many languages; all these numbers of states are optimal. After this, we completely characterize the class of languages recognized by 1-state GFAs, which is the only nontrivial class of languages recognized by 1-state automata. Finally, we consider the variations of PFAs, QFAs, and GFAs based on the notion of inclusive/exclusive cutpoint, and present some results on their expressive power.

Vorheriger Artikel Fast arithmetic in algorithmic self-assembly

Nächster Artikel Size-separable tile self-assembly: a tight bound for temperature-1 mismatch-free systems

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Whether Moore-Crutchfield quantum finite automata define more languages when the cutpoint is changed from 0 to a value from the open interval (0, 1).

MC stands for Moore and Crutchfield who introduced the model (Moore and Crutchfield 2000).

A GFA with \(v_0=0\) or \(f=0\) recognizes either \(\varnothing \) or \(\varSigma ^*\). The same effect can be achieved by setting all transition numbers to 0. Hence we assume w.l.o.g. \(v_0,\,f \ne 0\). We also use the standard convention that \(0^0=1\).

From the geometric point of view, a 1-state positive GFA defines a hyperplane in \({\mathbb {R}}^n\) and accepts exactly the words having the ends of their Parikh vectors on the prescribed side of this hyperplane.

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Titel: More on quantum, stochastic, and pseudo stochastic languages with few states
verfasst von: Arseny M. Shur
Abuzer Yakaryılmaz
Publikationsdatum: 01.03.2016
Verlag: Springer Netherlands
Erschienen in: Natural Computing / Ausgabe 1/2016
Print ISSN: 1567-7818
Elektronische ISSN: 1572-9796
DOI: https://doi.org/10.1007/s11047-015-9511-8

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