Created by W.Langdon from gp-bibliography.bib Revision:1.8081
Specifically, three main topics have been considered: (1) On-line evolutionary optimisation of hand-coded gaits for real, physical bipedal robots. The evolved gaits significantly outperformed the hand-coded gaits, reaching up to 65percent higher speed. (2) Evolution of bipedal gait controllers in simulators. First, linear genetic programming was used with two different simulated bipedal robots. In both these cases, the gait controller was evolved starting from programs consisting of random sequences of basic instructions. The best evolved programs generated stable bipedal locomotion, keeping the robot upright and moving indefinitely. However, the evolved gaits were not very human-like. Thus, a different approach, inspired by the neural mechanisms involved in the locomotion of biological organisms, was tried. Here, both the structure and parameters of a central pattern generator network, controlling the locomotion of a simulated robot, were optimised using a genetic algorithm. The evolved controllers generated a stable human-like gait and were also able to handle gait transitions. (3) Behavior selection in autonomous robots, using the utility function method. In particular, the performance of the method as a function of the polynomial degree of the utility functions was investigated. It was found that adequate behaviour selection systems can be found rapidly for low polynomial degrees (1-2), but also that the best solutions can only be obtained by using a higher polynomial degree (3-4). Furthermore, the performance of different evolutionary algorithms in connection with the utility function method was also investigated and, somewhat surprisingly, it was found that the standard method, employing a simple genetic algorithm, generally outperformed the modified methods.",
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Genetic Programming entries for Krister Wolff