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Revision as of 18:45, 16 October 2013
Computational Systems
This is the first block of the workshop series GMU:Self-Organisation by Design
Theory
Self-Organizing Systems usually have two components:
- Spacial Environment (i.e. Cellular Automaton or Vector field)
- Large number of Mobile Units (i.e. Particles or Agents)
In this workshop we will lear how to model those components in Processing, and how interactions between them can give rise to self-organizing behaviour.
Topics
- Simple Cellular Automata (CA)
- Discrete and Continuous CA
- CA on regular grids
- CA on irregular grids
- Multi-Level Cellular Automata
- Multilevel, Multiscale CA
- CA as Neural Networks
- Turing-McCabe Patterns
- Particle Systems
- Diffusion Limited Aggregation (DLA)
- Particle Physics
- Vector Fields
- Particles in static vector fields
- Particles in dynamic vector fields
Software
Some of the systems we are going to explore in Processing are
readily available in other software suites.
We will have a look at them and learn how to implement these systems from scratch.
Links
- New Kind of Science by Stephen Wolfram
- Cellular Automata in Shiffman's Nature of Code
- Particle Systems in Shiffman's Nature of Code
Experiments
This section will contain links to subpages and experiments of the participants.
Literature
A list of books and articles that are relevant to this part of the workshop will be published here.