The computational power of monodirectional tissue P systems with symport rules

The paper summarizes recent knowledge about computational power of spiking neural P systems and presents a sequence of new more general results. The concepts of recognizer SN P systems and of uniform families of SN P systems provide a formal framework for this study. We establish the relation of computational power of spiking neural P systems with various limitations to standard complexity classes like P , NP, PSPACE and P /poly.

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Evolution-Communication Spiking Neural P Systems

International Journal of Neural Systems ◽

10.1142/s0129065720500641 ◽

2020 ◽

pp. 2050064

Author(s):

Tingfang Wu ◽

Qiang Lyu ◽

Linqiang Pan

Keyword(s):

Parallel Computation ◽

Fire Behavior ◽

Information Storage ◽

P Systems ◽

Computational Power ◽

Spiking Neural P Systems ◽

Integrate And Fire ◽

Restricted Form ◽

The Family ◽

Novel Variant

Spiking neural P systems (SNP systems) are a class of distributed and parallel computation models, which are inspired by the way in which neurons process information through spikes, where the integrate-and-fire behavior of neurons and the distribution of produced spikes are achieved by spiking rules. In this work, a novel mechanism for separately describing the integrate-and-fire behavior of neurons and the distribution of produced spikes, and a novel variant of the SNP systems, named evolution-communication SNP (ECSNP) systems, is proposed. More precisely, the integrate-and-fire behavior of neurons is achieved by spike-evolution rules, and the distribution of produced spikes is achieved by spike-communication rules. Then, the computational power of ECSNP systems is examined. It is demonstrated that ECSNP systems are Turing universal as number-generating devices. Furthermore, the computational power of ECSNP systems with a restricted form, i.e. the quantity of spikes in each neuron throughout a computation does not exceed some constant, is also investigated, and it is shown that such restricted ECSNP systems can only characterize the family of semilinear number sets. These results manifest that the capacity of neurons for information storage (i.e. the quantity of spikes) has a critical impact on the ECSNP systems to achieve a desired computational power.

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Nonlinear Spiking Neural P Systems

International Journal of Neural Systems ◽

10.1142/s0129065720500082 ◽

2020 ◽

Vol 30 (10) ◽

pp. 2050008 ◽

Cited By ~ 7

Author(s):

Hong Peng ◽

Zeqiong Lv ◽

Bo Li ◽

Xiaohui Luo ◽

Jun Wang ◽

...

Keyword(s):

The State ◽

P Systems ◽

Number Generator ◽

Computational Power ◽

Nonlinear Functions ◽

Computing Systems ◽

Spiking Neural P Systems ◽

System A ◽

New Variant ◽

New Type

This paper proposes a new variant of spiking neural P systems (in short, SNP systems), nonlinear spiking neural P systems (in short, NSNP systems). In NSNP systems, the state of each neuron is denoted by a real number, and a real configuration vector is used to characterize the state of the whole system. A new type of spiking rules, nonlinear spiking rules, is introduced to handle the neuron’s firing, where the consumed and generated amounts of spikes are often expressed by the nonlinear functions of the state of the neuron. NSNP systems are a class of distributed parallel and nondeterministic computing systems. The computational power of NSNP systems is discussed. Specifically, it is proved that NSNP systems as number-generating/accepting devices are Turing-universal. Moreover, we establish two small universal NSNP systems for function computing and number generator, containing 117 neurons and 164 neurons, respectively.

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P SYSTEMS WORKING IN THE SEQUENTIAL MODE ON ARRAYS AND STRINGS

International Journal of Foundations of Computer Science ◽

10.1142/s0129054105003224 ◽

2005 ◽

Vol 16 (04) ◽

pp. 663-682 ◽

Cited By ~ 6

Author(s):

RUDOLF FREUND

Keyword(s):

P Systems ◽

General Definition ◽

Computational Power ◽

Generative Power ◽

Sequential Mode ◽

Definition Of

Based on a quite general definition of P systems where the rules are applied in a sequential way (and not in the maximally parallel way as it usually happens in most models of P systems considered so far in the literature), we investigate the generative power of various models of such P systems working in the sequential mode on arrays and strings, respectively. P systems working in the sequential mode on arrays/strings without priority relations for the rules reveal the same computational power as the corresponding matrix grammars without appearance checking working on arrays/strings. For obtaining the computational power of matrix grammars with appearance checking, priority relations for the rules (as one of many other possible additional features) are needed.

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ON THE POWER OF DETERMINISTIC AND SEQUENTIAL COMMUNICATING P SYSTEMS

International Journal of Foundations of Computer Science ◽

10.1142/s0129054107004759 ◽

2007 ◽

Vol 18 (02) ◽

pp. 415-431 ◽

Cited By ~ 1

Author(s):

LUDĚK CIENCIALA ◽

LUCIE CIENCIALOVÁ ◽

PIERLUIGI FRISCO ◽

PETR SOSÍK

Keyword(s):

The Other ◽

P Systems ◽

Computational Power ◽

Other Hand ◽

Mode 2 ◽

Parallel Mode ◽

Sequential Mode

We characterize the computational power of several restricted variants of communicating P systems. We show that 2-deterministic communicating P systems with 2 membranes, working in either minimally or maximally parallel mode, are computationally universal. Considering the sequential mode, 2 membranes are shown to characterize the power of partially blind multicounter machines. Next, a characterization of the power of 1-deterministic communicating P systems is given. Finally, we show that the nondeterministic variant in maximally parallel mode is universal already with 1 membrane. These results demonstrate differences in computational power between nondeterminism, 2-determinism and 1-determinism, on one hand, and between sequential, minimally and maximally parallel modes, on the other hand.

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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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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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