Von Neumann's Grown Systems

A Von Neumann's Grown Systems is a self-replicating system concept that envisions autonomous machines capable of self-assembly, evolution, and exponential growth through resource utilization and adaptive modification.

• AKA: Self-Replicating Automata, Von Neumann Machine, Grown vs Programmed Systems, Self-Evolving Machine Ecology.
• Context:
  • It can typically perform Self-Replication through component assembly.
  • It can typically execute Self-Modification through design iteration.
  • It can typically achieve Resource Harvesting through material processing.
  • It can typically enable Evolutionary Adaptation through selective pressure.
  • ...
  • It can often demonstrate Emergent Complexity through generational change.
  • It can often achieve Exponential Expansion through parallel replication.
  • It can often develop Specialized Variants through environmental adaptation.
  • ...
  • It can range from being a Simple Von Neumann's Grown Systems to being a Complex Von Neumann's Grown Systems, depending on its grown system sophistication.
  • It can range from being a Terrestrial Von Neumann's Grown Systems to being a Interstellar Von Neumann's Grown Systems, depending on its grown system operational domain.
  • ...
  • It can integrate with Von Neumann Probe for space exploration.
  • It can connect to Software 4.0 Development Model for digital evolution.
  • It can interface with Superintelligences Expansion Period for future scenario.
  • It can communicate with AI Ethics for control consideration.
  • ...
• Example(s):
  • Theoretical Implementations, such as:
    • Universal Constructor for arbitrary object building.
    • Kinematic Model for mechanical self-assembly.
    • Cellular Automata Implementation for computational substrate.
  • Modern AI Parallels, such as:
    • Self-Improving AI Systems for capability enhancement.
    • AutoML Platforms for architecture evolution.
    • Neural Architecture Search for design optimization.
  • Physical Realization Concepts, such as:
    • 3D Printer Networks for manufacturing chain.
    • Robotic Ecosystems for collaborative construction.
    • Molecular Assemblers for nanoscale replication.
  • ...
• Counter-Example(s):
  • Static Programmed System, which lacks self-modification.
  • Centrally Controlled Robot, which lacks autonomous evolution.
  • Fixed-Design Machine, which lacks adaptive capability.
• See: Von Neumann Probe, Software 4.0 Development Model, Superintelligences Expansion Period, Self-Replicating System, Artificial Life, Evolutionary Robotics, Existential Risk.