Contributed talk in Perception 1, July 29, 2019, 3 p.m. in room USB.4.005

Measuring properties of movement in populations of evolved 3D agents

Maciej Komosinski, Konrad Miazga

watch Publication Although determining the similarity of genotypes is often employed in artificial life experiments to measure or control diversity, in practical applications we may often be more interested in similarities of phenotypes. The latter may provide information about the effective diversity in a population, and thus it may be more suitable for diversity estimations and diversity-based search algorithms. A phenotype of a simulated creature can be understood as creature's physiology or its behavior - e.g., movement patterns. In this paper, we introduce a set of efficient measures which allow for describing the movement of simulated 3D stick creatures. We use these measures to analyze the results of evolutionary optimization of virtual creatures towards four unique behavioral goals. We show that most solutions obtained for each goal occupy distinct areas of the phenotype space. This suggests that measures defined in this paper create a useful behavioral space for movement-related fitness functions. Finally, we use the introduced measures to visualize how their values change in populations during the course of evolution.