CAP6938 Neuroevolution and Artificial Embryogeny Approaches to Neuroevolution

1. CAP6938Neuroevolution and Artificial EmbryogenyApproaches toNeuroevolution Dr. Kenneth Stanley February 1, 2006

2. Many TWEANN Problems • Competing conventions problem • Topology matching problem • Initial population topology randomization • Defective starter genomes • Unnecessarily high-dimensional search space • Loss of innovative structures • More complex can’t compete in the short run • Need to protect innovation • How do researchers design NE methods?

3. Breeder Genetic Programming (Zhang and Muhlenbein) • Represent network as a tree (TWEANN) • Only crossover adapts topology • Attempt to minimize both complexity and error: • Tested with parity and majority functions

4. Parallel Distributed Genetic Programming (PDGP)Pujol and Poli (1997) • “Dual representation”: linear and graph

5. Parallel Distributed Genetic Programming (PDGP)Pujol and Poli (1997) • 2D genome uses overrepresentation • Several crossover operators use properties of both 1D and 2D representations (e.g. subgraph swapping) • Also several mutation operators • Fixed-sized genome • Also tested on parity (and later control)

6. GeNeralized Acquisition of Recurrent Links(GNARL)Angeline, Saunders, and Pollack (1993) • “Thus, the prospect of evolving connectionist networks with crossover appears limited in general, and better results should be expected with reproduction heuristics that respect the uniqueness of the distributed representations.” • Random initial networks • Fixed-sized genomes • Structural mutations • Tested with “Inducing Languages” and “Ant Problem”

7. Structured Genetic Algorithm (sGA)Dasgupta and McGregor (1992) • “Standard” matrix representation • Size of matrix is square of # nodes • Maximum net size for fixed matrix size • No thought to crossover (just plain GA) • Tested on “multi-solution functions”

8. Cellular EncodingGruau (1993, 1996) • Indirect encoding (Artificial Embryogeny) • First method to balance 2 poles without velocity inputs • Biological motivation: grow from single cell • Gruau proved CE can generate any graph • Crossover swaps subtrees like GP • Indirect encoding only makes competing conventions harder to comprehend

9. Cellular EncodingGruau (1993,1996)

10. Enforced SubPopulations (ESP)Gomez and Miikkulainen (1997,1999) • Fixed-topology successor to Symbiotic Adaptive NeuroEvolution (SANE; Moriarty and Miikkulainen 1996) • Neurons evolved in subpopulations • One subpopulation for each hidden neuron • Cooperative coevolution • Interesting circumvention of competing conventions

11. ESP defeats CE Hidden Nodes Inputs (Gomez and Miikkulainen 1999)

12. TWEANNS need Principles • Is there a principled method for evolving topologies that is not ad hoc? • How can the TWEANN challenges be handled directly? • Are all TWEANNs created equal?

13. Next Class: NeuroEvolution of Augmenting Topologies (NEAT) • Directly address TWEANN challenges • Turns topology into an advantage • Applicable outside NN’s • Basis of class projects Evolving Neural Networks Through Augmenting Topologies by Kenneth O. Stanley and Risto Miikkulainen (2002) Homework due 2/6/05: 1 page project proposal including project description and goals, a falsifiable hypothesis on what you expect to happen, why it involves structure, and what platform you will use (language and OS). If partners, describe briefly division of labor.