Cellular automata machines: a new environment for modeling
Cellular automata machines: a new environment for modeling
Evolution of Parallel Cellular Machines: The Cellular Programming Approach
Evolution of Parallel Cellular Machines: The Cellular Programming Approach
An interactive self-replicator implemented in hardware
Artificial Life
The BioWall: An Electronic Tissue for Prototyping Bio-Inspired Systems
EH '02 Proceedings of the 2002 NASA/DoD Conference on Evolvable Hardware (EH'02)
Theory of Self-Reproducing Automata
Theory of Self-Reproducing Automata
From Data and Signals Cellular Automata to Self-organizing Circuits
ACRI '08 Proceedings of the 8th international conference on Cellular Automata for Reseach and Industry
Design of self-organizing bio-inspired systems
International Journal of Knowledge-based and Intelligent Engineering Systems - Adaptive Hardwarel / Evolvable Hardware
Self-organizing configurable bit slice processors
CEC'09 Proceedings of the Eleventh conference on Congress on Evolutionary Computation
Self-organizing systems based on bio-inspired properties
ECAL'07 Proceedings of the 9th European conference on Advances in artificial life
Bio-inspired systems with self-developing mechanisms
ICES'07 Proceedings of the 7th international conference on Evolvable systems: from biology to hardware
Construction-based and inspection-based universal self-replication
ECAL'05 Proceedings of the 8th European conference on Advances in Artificial Life
Hardware implementation of 3d self-replication
ICES'05 Proceedings of the 6th international conference on Evolvable Systems: from Biology to Hardware
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In a traditional cellular automaton (CA) a cell is implemented by a rule table defining its state at the next time step, given its present state and those of its neighbors. The cell thus deals only with states. We present a novel CA where the cell handles data and signals. The cell is designed as a digital system comprising a processing unit and a control unit. This allows the realization of various growing structures, including self-replicating loops and biomorphs. We also describe the hardware implementation of these structures within our electronic wall for bio-inspired applications, the BioWall.