Journal of Computer and System Sciences
Handbook of Formal Languages
Membrane Computing: An Introduction
Membrane Computing: An Introduction
The power of communication: P systems with symport/antiport
New Generation Computing
Unexpected Universality Results for Three Classes of P Systems with Symport/Antiport
DNA8 Revised Papers from the 8th International Workshop on DNA Based Computers: DNA Computing
Computation: finite and infinite machines
Computation: finite and infinite machines
Counting time in computing with cells
DNA'05 Proceedings of the 11th international conference on DNA Computing
Computational power of symport/antiport: history, advances, and open problems
WMC'05 Proceedings of the 6th international conference on Membrane Computing
On the computational power of the mate/bud/drip brane calculus: interleaving vs. maximal parallelism
WMC'05 Proceedings of the 6th international conference on Membrane Computing
Asynchronous p systems and p systems working in the sequential mode
WMC'04 Proceedings of the 5th international conference on Membrane Computing
Communicative p systems with minimal cooperation
WMC'04 Proceedings of the 5th international conference on Membrane Computing
CMSB'04 Proceedings of the 20 international conference on Computational Methods in Systems Biology
Membrane Computing and Brane Calculi (Some Personal Notes)
Electronic Notes in Theoretical Computer Science (ENTCS)
Membrane computing and brane calculi. Old, new, and future bridges
Theoretical Computer Science
Theoretical Computer Science
On the Computational Power of Flip-Flop Proteins on Membranes
CiE '07 Proceedings of the 3rd conference on Computability in Europe: Computation and Logic in the Real World
Computing with cells: membrane systems-some complexity issues
International Journal of Parallel, Emergent and Distributed Systems
Cell Cycle and Tumor Growth in Membrane Systems with Peripheral Proteins
Electronic Notes in Theoretical Computer Science (ENTCS)
Membrane computing with transport and embedded proteins
Theoretical Computer Science
Sequential SNP systems based on min/max spike number
Theoretical Computer Science
On flip-flop membrane systems with proteins
WMC'07 Proceedings of the 8th international conference on Membrane computing
On the verification of membrane systems with dynamic structure
Natural Computing: an international journal
An overview of membrane computing
ICDCIT'11 Proceedings of the 7th international conference on Distributed computing and internet technology
Selected topics in computational complexity of membrane systems
Computation, cooperation, and life
P systems with proteins on membranes and membrane division
DLT'06 Proceedings of the 10th international conference on Developments in Language Theory
On the power of computing with proteins on membranes
WMC'09 Proceedings of the 10th international conference on Membrane Computing
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This work is a continuation of the investigations aiming to bridge membrane computing (where in a compartmental cell-like structure the chemicals to evolve are placed in the compartments defined by the membranes) and brane calculi (where one considers again a compartmental cell-like structure with the chemicals/proteins placed on the membranes themselves). In the current paper we use objects both in compartments and on membranes (the latter are called proteins), with the objects from membranes evolving under the control of the proteins. Several possibilities are considered (objects only moved across membranes or also changed during this operation, with the proteins only assisting the move/change or also changing themselves). Somewhat expected, computational universality is obtained for several combinations of such possibilities.