On the Computational Power of 1-Deterministic and Sequential P Systems

  • Authors:

  • Oscar H. Ibarra;Sara Woodworth;Hsu-Chun Yen;Zhe Dang

  • Affiliations:

  • Department of Computer Science, University of California Santa Barbara, CA 93106, USA. E-mails: ibarra@cs.ucsb.edu/ swood@cs.ucsb.edu;Department of Computer Science, University of California Santa Barbara, CA 93106, USA. E-mails: ibarra@cs.ucsb.edu/ swood@cs.ucsb.edu;Department of Electrical Engineering, National Taiwan University Taipei, Taiwan. E-mail: yen@cc.ee.ntu.edu.tw;School of Electrical Engineering and Computer Science Washington State University Pullman, WA 99164, USA. E-mail: zdang@eecs.wsu.edu

  • Venue:
  • Fundamenta Informaticae - SPECIAL ISSUE ON TRAJECTORIES OF LANGUAGE THEORY Dedicated to the memory of Alexandru Mateescu
  • Year:
  • 2006

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Abstract

The original definition of P systems calls for rules to be applied in a maximally parallel fashion. However, in some cases a sequential model may be a more reasonable assumption. Here we study the computational power of different variants of sequential P systems. Initially we look at cooperative systems operating on symbol objects and without prioritized rules, but which allow membrane dissolution and bounded creation rules. We show that they are equivalent to vector addition systems and, hence, nonuniversal. When these systems are used as language acceptors, they are equivalent to communicating P systems which, in turn, are equivalent to partially blind multicounter machines. In contrast, if such cooperative systems are allowed to create an unbounded number of new membranes (i.e., with unbounded membrane creation rules) during the course of the computation, then they become universal. We then consider systems with prioritized rules operating on symbol objects. We show two types of results: there are sequential P systems that are universal and sequential P systems that are nonuniversal. In particular, both communicating and cooperative P systems are universal, even if restricted to 1-deterministic systems with one membrane. However, the reachability problem for multi-membrane catalytic P systems with prioritized rules is NP-complete and, hence, these systems are nonuniversal.