Evolving optimal learning strategies for robust locomotion in the spring-loaded inverted pendulum model

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Abstract

Robust locomotion in a wide range of environments is still beyond the capabilities of robots. In this article, we explore how exploiting the soft morphology can be used to achieve stability in the commonly used spring-loaded inverted pendulum model. We evolve adaption rules that dictate how the attack angle and stiffness of the model should be changed to achieve stability for both offline and online learning over a range of starting conditions. The best evolved rules, for both the offline and online learning, are able to find stability from a significantly wider range of starting conditions when compared to an un-adapting model. This is achieved through the interplay between adapting both the control and the soft morphological parameters. We also show how when using the optimal online rule set, the spring-loaded inverted pendulum model is able to robustly withstand changes in ground level of up to 10 m downwards step size.

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APA

Walker, K., & Hauser, H. (2019). Evolving optimal learning strategies for robust locomotion in the spring-loaded inverted pendulum model. International Journal of Advanced Robotic Systems, 16(6). https://doi.org/10.1177/1729881419885701

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