MOVE: a framework for high-performance processor design
Proceedings of the 1991 ACM/IEEE conference on Supercomputing
A robust multiplexer-based FPGA inspired by biological systems
Journal of Systems Architecture: the EUROMICRO Journal - Special issue: dependable parallel computer systems
Configuration cloning: exploiting regularity in dynamic DSP architectures
FPGA '99 Proceedings of the 1999 ACM/SIGDA seventh international symposium on Field programmable gate arrays
Communications of the ACM
IEEE Spectrum
Microprocessor Architectures: From VLIW to Tta
Microprocessor Architectures: From VLIW to Tta
IEEE Design & Test
Self-Inspection Based Reproduction in Cellular Automata
Proceedings of the Third European Conference on Advances in Artificial Life
Phylogeny, Ontogeny, and Epigenesis: Three Sources of Biological Inspiration for Softening Hardware
ICES '96 Proceedings of the First International Conference on Evolvable Systems: From Biology to Hardware
An In-System Routing Strategy For Evolvable Hardware Programmable Platforms
EH '01 Proceedings of the The 3rd NASA/DoD Workshop on Evolvable Hardware
Theory of Self-Reproducing Automata
Theory of Self-Reproducing Automata
POEtic tissue: an integrated architecture for bio-inspired hardware
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
A phylogenetic, ontogenetic, and epigenetic view of bio-inspired hardware systems
IEEE Transactions on Evolutionary Computation
Engineering of Software-Intensive Systems: State of the Art and Research Challenges
Software-Intensive Systems and New Computing Paradigms
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The multicellular structure of biological organisms and the interpretation in each of their cells of a chemical program (the DNA string or genome) is the source of inspiration for the Embryonics (embryonic electronics) project, whose final objective is the design of highly robust integrated circuits, endowed with properties usually associated with the living world: self-repair and self-replication. In this article, we provide an overview of our latest research in the domain of the self-replication of processing elements within a programmable logic substrate, a key prerequisite for achieving system-level fault tolerance in our bio-inspired approach.