Add to ORKGIn this paper we consider three restricted variants of P systems with active membranes: (1) P systems using out communication rules only, (2) P systems using elementary membrane division and dissolution rules only, and (3) polarizationless P systems using dissolution and restricted evolution rules only. We show that every problem in P can be solved with uniform families of any of these variants. This, using known results on the upper bound of the computational power of variants (1) and (3) yields new characterizations of the class P. In the case of variant (2) we provide a further characterization of P by giving a semantic restriction on the computations of P systems of this varian
P systems with active membranes using only two electrical charges and only rules of types (a) and (...
We prove that uniform families of P systems with active membranes operat- ing in polynomial time ca...
We identify a family of decision problems that are hard for some complexity classes defined in term...
We study the computational efficiency of recognizer P systems with active membranes without polariz...
Recognizer P systems with active membranes have proven to be very powerful computing devices, being...
In this paper we study membrane dissolution rules in the framework of P systems with active membran...
Membrane computing is a computing paradigm providing a class of distributed parallel computing devi...
The aim of this paper is to study the computational power of P systems with one active membrane wit...
Membrane computing is a computing paradigm providing a class of distributed parallel computing devi...
We investigate polarizationless P systems with active membranes working in maximally parallel manne...
We continue the study of P systems with mobile membranes introduced in [7], which is a variant of P ...
We investigate the computing power and the efficiency of P systems with active membranes without po...
P systems with active membranes, in their classical definition, make use of noncooperative rules on...
We study a P˘aun’s conjecture concerning the unsolvability of NP–complete problems by polarizationl...
P systems with active membranes are a class of computation models in the area ofmembrane computing, ...
P systems with active membranes using only two electrical charges and only rules of types (a) and (...
We prove that uniform families of P systems with active membranes operat- ing in polynomial time ca...
We identify a family of decision problems that are hard for some complexity classes defined in term...
We study the computational efficiency of recognizer P systems with active membranes without polariz...
Recognizer P systems with active membranes have proven to be very powerful computing devices, being...
In this paper we study membrane dissolution rules in the framework of P systems with active membran...
Membrane computing is a computing paradigm providing a class of distributed parallel computing devi...
The aim of this paper is to study the computational power of P systems with one active membrane wit...
Membrane computing is a computing paradigm providing a class of distributed parallel computing devi...
We investigate polarizationless P systems with active membranes working in maximally parallel manne...
We continue the study of P systems with mobile membranes introduced in [7], which is a variant of P ...
We investigate the computing power and the efficiency of P systems with active membranes without po...
P systems with active membranes, in their classical definition, make use of noncooperative rules on...
We study a P˘aun’s conjecture concerning the unsolvability of NP–complete problems by polarizationl...
P systems with active membranes are a class of computation models in the area ofmembrane computing, ...
P systems with active membranes using only two electrical charges and only rules of types (a) and (...
We prove that uniform families of P systems with active membranes operat- ing in polynomial time ca...
We identify a family of decision problems that are hard for some complexity classes defined in term...