Tuning Frontiers of Efficiency in Tissue P Systems with Evolutional Communication Rules

Over the last few years, a new methodology to address the P versus NP problem has been developed, based on searching for borderlines between the nonefficiency of computing models (only problems in class P can be solved in polynomial time) and the presumed efficiency (ability to solve NP-complete problems in polynomial time). These borderlines can be seen as frontiers of efficiency, which are crucial in this methodology. “Translating,” in some sense, an efficient solution in a presumably efficient model to an efficient solution in a nonefficient model would give an affirmative answer to problem P versus NP. In the framework of Membrane Computing, the key of this approach is to detect the syntactic or semantic ingredients that are needed to pass from a nonefficient class of membrane systems to a presumably efficient one. This paper deals with tissue P systems with communication rules of type symport/antiport allowing the evolution of the objects triggering the rules. In previous works, frontiers of efficiency were found in these kinds of membrane systems both with division rules and with separation rules. However, since they were not optimal, it is interesting to refine these frontiers. In this work, optimal frontiers of the efficiency are obtained in terms of the total number of objects involved in the communication rules used for that kind of membrane systems. These optimizations could be easier to translate, if possible, to efficient solutions in a nonefficient model.

[1]  Gheorghe Paun,et al.  Membrane Computing, 10th International Workshop, WMC 2009, Curtea de Arges, Romania, August 24-27, 2009. Revised Selected and Invited Papers , 2010, Workshop on Membrane Computing.

[2]  Gheorghe Paun,et al.  Membrane Computing , 2002, Natural Computing Series.

[3]  Agustín Riscos-Núñez,et al.  P systems with proteins: a new frontier when membrane division disappears , 2019, J. Membr. Comput..

[4]  Linqiang Pan,et al.  The Computational Complexity of Tissue P Systems with Evolutional Symport/Antiport Rules , 2018, Complex..

[5]  Linqiang Pan,et al.  Tissue-like P systems with evolutional symport/antiport rules , 2017, Inf. Sci..

[6]  Gheorghe Paun,et al.  Computing with Membranes , 2000, J. Comput. Syst. Sci..

[7]  Giancarlo Mauri,et al.  Solving NP-Complete Problems Using P Systems with Active Membranes , 2000, UMC.

[8]  Mario de Jesús Pérez Jiménez,et al.  An Optimal Frontier of the Efficiency of Tissue P Systems with Cell Division , 2012 .

[9]  Petr Sosík,et al.  Improving the Efficiency of Tissue P Systems with Cell Separation , 2009 .

[10]  Pierluigi Frisco,et al.  Applications of Membrane Computing in Systems and Synthetic Biology , 2014 .

[11]  Alfonso Rodríguez-Patón,et al.  A New Class of Symbolic Abstract Neural Nets: Tissue P Systems , 2002, COCOON.

[12]  Mario J. Pérez-Jiménez,et al.  Computational complexity of tissue-like P systems , 2010, J. Complex..

[13]  Marian Gheorghe,et al.  Real-life Applications with Membrane Computing , 2017 .

[14]  Maoguo Gong,et al.  Bio-inspired Computing – Theories and Applications , 2016, Communications in Computer and Information Science.