Symbolic Boolean manipulation with ordered binary-decision diagrams
ACM Computing Surveys (CSUR)
A robust multiplexer-based FPGA inspired by biological systems
Journal of Systems Architecture: the EUROMICRO Journal - Special issue: dependable parallel computer systems
Self-replicating and self-repairing multicellular automata
Artificial Life - Special issue on self-replication
Algorithms and Data Structures in VLSI Design
Algorithms and Data Structures in VLSI Design
Self-Repairing Multicellular Hardware: A Reliability Analysis
ECAL '99 Proceedings of the 5th European Conference on Advances in Artificial Life
Reliability Analysis in Self-Repairing Embryonic Systems
EH '99 Proceedings of the 1st NASA/DOD workshop on Evolvable Hardware
Biowatch: A Giant Electronic Bio-Inspired Watch
EH '01 Proceedings of the The 3rd NASA/DoD Workshop on Evolvable Hardware
IEEE Transactions on Computers
A biological programming model for self-healing
Proceedings of the 2003 ACM workshop on Survivable and self-regenerative systems: in association with 10th ACM Conference on Computer and Communications Security
Embryonics: A Path to Artificial Life?
Artificial Life
Evolutionary and embryogenic approaches to autonomic systems
Proceedings of the 3rd International Conference on Performance Evaluation Methodologies and Tools
Developmental models for emergent computation
ICES'03 Proceedings of the 5th international conference on Evolvable systems: from biology to hardware
MOVE processors that self-replicate and differentiate
BioADIT'06 Proceedings of the Second international conference on Biologically Inspired Approaches to Advanced Information Technology
Online marking of defective cells by random flies
ACRI'06 Proceedings of the 7th international conference on Cellular Automata for Research and Industry
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The Embryonics project is inspired by some of the basic processes of molecular biology, such as the embryonic development of living beings. Transposing these processes in to digital electronic integrated circuits, we design artificial organisms endowed with properties typical of to the living world, such as self-repair and self-healing. In order to illustrate the original features of the Embryonics project, we define the cellular and molecular architecture of a giant artificial organism, the BioWatch. The hardware implementation of a microprogrammed version of our watch exploits a new reconfigurable tissue, the bio-inspired electronic wall or BioWall.