Simulation of P Systems with Active Membranes on CUDA

Ramsey numbers deal with conditions when a combinatorial object necessarily contains some smaller given objects. It is well known that it is very difficult to obtain the values of Ramsey numbers. In this work, a theoretical chemical/biological solution is presented in terms of membrane computing for the decision version of Ramsey number problem, that is, to decide whether an integer n is the value of Ramsey number R(k, l), where k and l are integers.

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Recent complexity-theoretic results on P systems with active membranes

Journal of Logic and Computation ◽

10.1093/logcom/exs077 ◽

2013 ◽

Vol 25 (4) ◽

pp. 1047-1071 ◽

Cited By ~ 5

Author(s):

Giancarlo Mauri ◽

Alberto Leporati ◽

Antonio E. Porreca ◽

Claudio Zandron

Keyword(s):

P Systems ◽

Active Membranes

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The computational power of timed P systems with active membranes using promoters

Mathematical Structures in Computer Science ◽

10.1017/s0960129518000282 ◽

2018 ◽

Vol 29 (5) ◽

pp. 663-680 ◽

Cited By ~ 2

Author(s):

YUEGUO LUO ◽

HAIJUN TAN ◽

YING ZHANG ◽

YUN JIANG

Keyword(s):

P Systems ◽

P System ◽

Computational Power ◽

Computable Set ◽

Complete Problem ◽

Active Membranes ◽

New Variant ◽

Uniform Solution ◽

Bioinspired Computing ◽

Computing Models

P systems with active membranes are a class of bioinspired computing models, where the rules are used in the non-deterministic maximally parallel manner. In this paper, first, a new variant of timed P systems with active membranes is proposed, where the application of rules can be regulated by promoters with only two polarizations. Next, we prove that any Turing computable set of numbers can be generated by such a P system in the time-free way. Moreover, we construct a uniform solution to the$\mathcal{SAT}$problem in the framework of such recognizer timed P systems in polynomial time, and the feasibility and effectiveness of the proposed system is demonstrated by an instance. Compared with the existing methods, the P systems constructed in our work require fewer necessary resources and RS-steps, which show that the solution is effective toNP-complete problem.

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Accelerated P systems with active membranes on a graphics processing unit

Asian Conference on Membrane Computing ACMC 2014 ◽

10.1109/acmc.2014.7065803 ◽

2014 ◽

Author(s):

Ali Maroosi ◽

Ravie Muniyandi

Keyword(s):

Graphics Processing Unit ◽

P Systems ◽

Processing Unit ◽

Active Membranes ◽

Graphics Processing

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On the power of P systems with active membranes using weak non-elementary membrane division

Journal of Membrane Computing ◽

10.1007/s41965-021-00082-2 ◽

2021 ◽

Author(s):

Zsolt Gazdag ◽

Károly Hajagos ◽

Szabolcs Iván

Keyword(s):

Polynomial Time ◽

P Systems ◽

Computational Power ◽

Complete Problems ◽

Active Membranes ◽

Membrane Division ◽

Elementary Membrane

AbstractIt is known that polarizationless P systems with active membranes can solve $$\mathrm {PSPACE}$$ PSPACE -complete problems in polynomial time without using in-communication rules but using the classical (also called strong) non-elementary membrane division rules. In this paper, we show that this holds also when in-communication rules are allowed but strong non-elementary division rules are replaced with weak non-elementary division rules, a type of rule which is an extension of elementary membrane divisions to non-elementary membranes. Since it is known that without in-communication rules, these P systems can solve in polynomial time only problems in $$\mathrm {P}^{\text {NP}}$$ P NP , our result proves that these rules serve as a borderline between $$\mathrm {P}^{\text {NP}}$$ P NP and $$\mathrm {PSPACE}$$ PSPACE concerning the computational power of these P systems.

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