Using Indirect Encoding of Multiple Brains to Produce Multimodal Behavior

Abstract: An important challenge in neuroevolution is to evolve complex neural networks with multiple modes of behavior. Indirect encodings can potentially answer this challenge. Yet in practice, indirect encodings do not yield effective multimodal controllers. Thus, this paper introduces novel multimodal extensions to HyperNEAT, a popular indirect encoding. A previous multimodal HyperNEAT approach called situational policy geometry assumes that multiple brains benefit from being embedded within an explicit geometric sp… Show more

“…An output signal of the CPPN indicates the weight of the connection. Motivated by this approach, a number of variants were proposed to evolve even larger-scale networks [44][45][46][47]. Moreover, algorithms were also proposed that replace NEAT as the CPPN constructor with genetic programming [48].…”

Hill-Climb-Assembler Encoding: Evolution of Small/Mid-Scale Artificial Neural Networks for Classification and Control Problems

“…An output signal of the CPPN indicates the weight of the connection. Motivated by this approach, a number of variants were proposed to evolve even larger-scale networks [44][45][46][47]. Moreover, algorithms were also proposed that replace NEAT as the CPPN constructor with genetic programming [48].…”

Hill-Climb-Assembler Encoding: Evolution of Small/Mid-Scale Artificial Neural Networks for Classification and Control Problems