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Towards Robust Bio-Inspired Circuits: The Embryonics Approach. ECAL’99, Lausanne September 15, 1999. Caenorhabditis Elegans. 11 December 1998. Caenorhabditis Elegans. From S.F. Gilbert, Developmental Biology, Sinauer, 1991. Multicellular Organization. 959 somatic cells.
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Towards Robust Bio-Inspired Circuits: The Embryonics Approach Daniel Mange ECAL’99, Lausanne September 15, 1999
Caenorhabditis Elegans 11 December 1998 Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Caenorhabditis Elegans From S.F. Gilbert, Developmental Biology, Sinauer, 1991 Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Multicellular Organization 959 somatic cells Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Cellular Division Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Cellular Differentiation Pharynx Intestine Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Embryonics: Why? Design of robust integrated circuits able to: • self-repair (healing) • self-replicate (cloning) Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Embryonics: How? Iterative electronic circuit based on 3 features: • multicellular organization • cellular division • cellular differentiation Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Electronic Implementation Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Multicellular Organization Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Embryonics Landscape Towards Robust Bio-Inspired Circuits: The Embryonics Approach
StopWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach
StopWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach
StopWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach
StopWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach
StopWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach
StopWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Cellular Differentiation Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Self-Replication Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Self-Replication Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Self-Repair Towards Robust Bio-Inspired Circuits: The Embryonics Approach
BioWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach
BioWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Embryonics Landscape Towards Robust Bio-Inspired Circuits: The Embryonics Approach
MUXTREE Molecule Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Space Divider Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Space Divider Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Cellular Self-Replication Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Cellular Self-Repair Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Cellular Self-Repair Towards Robust Bio-Inspired Circuits: The Embryonics Approach
The MUXTREE Molecule Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Molecular Implementation Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Embryonics Landscape Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Artificial Genome Towards Robust Bio-Inspired Circuits: The Embryonics Approach
The Future of Embryonics Towards Robust Bio-Inspired Circuits: The Embryonics Approach
Towards Robust Bio-Inspired Circuits: The Embryonics Approach
