13th International Conference on Membrane Computing - MTA Sztaki

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<strong>13th</strong> <strong>International</strong> <strong>Conference</strong> on Membrane Computing, CMC13, Budapest, Hungary, August 28 - 31, 2012. Proceedings, pages 115 - 124. One-Membrane Symport P Systems with Few Extra Symbols Artiom Alhazov 1,2 and Yurii Rogozhin 2 1 Università degli Studi di Milano-Bicocca Dipartimento di Informatica, Sistemistica e Comunicazione Viale Sarca 336, 20126 Milano, Italy E-mail: artiom.alhazov@unimib.it 2 Institute of Mathematics and Computer Science Academy of Sciences of Moldova Academiei 5, Chişinău MD-2028 Moldova E-mail: {artiom,rogozhin}@math.md Abstract. Membrane systems (with symbol objects) are formal models of distributed parallel multiset processing. Symport rules move multiple objects to a neighboring region. It is known that for P systems with symport rules of weight at most 3 and a single membrane, 7 superfluous symbols are enough for computational completeness, and 1 is necessary. We improve the lower bounds on the generative power of P systems with symport of weight bounded by 3 and 4, in particular establishing that 6 and 2 extra symbols suffice, respectively. 1 Introduction Membrane systems (with symbol objects) are formal models of distributed parallel multiset processing. Symport rules move predefined groups objects to a neighboring region [7]. In the maximally parallel mode (typical for membrane computing), this alone is sufficient to construct a computationally universal device, as long as the environment may contain an unbounded supply of some objects. The number of symbols specified in a symport rule is called its weight. The result of a computation is the total number of objects when the system halts. In some cases, however, for technical reasons the desired result may only be obtained alongside a small number of superfluous objects in the output region. There were multiple papers improving the results on P systems with symport/antiport of small weight (an antiport rule moves objects between 2 regions in both directions, and its weight is the maximum of objects per direction), see [5] for a survey of results. Computational completeness is achieved even for minimal cooperation: either symport/antiport of weight 1, or symport of weight at most 2. This holds for 2 membranes, without superfluous objects if the output is considered in the skin, or with 1 superfluous object under the classical assumption of the output in the elementary membrane. In the tissue case, the accepting systems can even be made deterministic. 115
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Erzsébet Csuhaj-Varjú Marian Gheo
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Editors Erzsébet Csuhaj-Varjú Dep
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Preface In addition to the texts or
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Contents M.A. Martínez-del-Amor, I
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(Tissue) P systems with decaying ob
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Turing’s three pioneering initiat
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Turing’s three pioneering initiat
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MP systems for systems biology tere
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Yu. Rogozhin this obstacle and to g
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Yu. Rogozhin 10. J. Cocke, M. Minsk
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A formal framework for P systems wi
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A new approach for solving SAT by P
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Maintenance of chronobiological inf
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Membranes with local environments A
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Simplifying Event-B models of P sys
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Author Index Adorna H., 143 Agrigor
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13th International Conference on Membrane Computing - MTA Sztaki

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