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Advancing Bio-Inspired Circuits Through the Embryonics Approach

This paper presents the Embryonics approach to developing robust, bio-inspired circuits modeled after the mechanisms of cellular organization, division, and differentiation found in multicellular organisms, particularly Caenorhabditis elegans. By integrating features such as self-repair and self-replication, this innovative design aims to enhance the resilience and adaptability of electronic systems. The study explores various implementations including the MUXTREE molecule and emphasizes the importance of simulating biological processes in circuit design for future advancements in electronics.

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Advancing Bio-Inspired Circuits Through the Embryonics Approach

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  1. Towards Robust Bio-Inspired Circuits: The Embryonics Approach Daniel Mange ECAL’99, Lausanne September 15, 1999

  2. Caenorhabditis Elegans 11 December 1998 Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  3. Caenorhabditis Elegans From S.F. Gilbert, Developmental Biology, Sinauer, 1991 Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  4. Multicellular Organization 959 somatic cells Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  5. Cellular Division Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  6. Cellular Differentiation Pharynx Intestine Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  7. Embryonics: Why? Design of robust integrated circuits able to: • self-repair (healing) • self-replicate (cloning) Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  8. Embryonics: How? Iterative electronic circuit based on 3 features: • multicellular organization • cellular division • cellular differentiation Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  9. Electronic Implementation Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  10. Multicellular Organization Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  11. Embryonics Landscape Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  12. StopWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  13. StopWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  14. StopWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  15. StopWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  16. StopWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  17. StopWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  18. Cellular Differentiation Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  19. Self-Replication Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  20. Self-Replication Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  21. Self-Repair Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  22. BioWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  23. BioWatch Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  24. Embryonics Landscape Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  25. MUXTREE Molecule Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  26. Space Divider Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  27. Space Divider Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  28. Cellular Self-Replication Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  29. Cellular Self-Repair Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  30. Cellular Self-Repair Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  31. The MUXTREE Molecule Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  32. Molecular Implementation Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  33. Embryonics Landscape Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  34. Artificial Genome Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  35. The Future of Embryonics Towards Robust Bio-Inspired Circuits: The Embryonics Approach

  36. Towards Robust Bio-Inspired Circuits: The Embryonics Approach

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