A survey on evolutionary-aided design in robotics

Prabhu, Shanker G. R.; Seals, R. C.; Kyberd, Peter; Wetherall, Jodie

doi:10.1017/s0263574718000747

Cited by 20 publications

(4 citation statements)

References 102 publications

(385 reference statements)

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“…To avoid sub-optimality and limitations brought by empirical design, there are a growing number of evolutionary and learning-based methods to optimize motion of modular robots [18], [19]. Genetic algorithm (GA) was utilized to search and optimize locomotion gaits of modular robotic systems of the M-Tran, iMobot and UBot robots in various environments [20]- [22].…”

Section: Introductionmentioning

confidence: 99%

Co-optimization of Morphology and Behavior of Modular Robots via Hierarchical Deep Reinforcement Learning

Sun,

Yao,

Xiao

et al. 2023

Robotics: Science and Systems XIX

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Modular robots hold the promise of changing their shape and even dimension to adapt to various tasks and environments. To realize this superiority, it is essential to find the appropriate morphology and its corresponding behavior simultaneously to ensure optimality of the reconfiguration. However, achieving co-optimization is challenging because robotic configuration and motion are interactive and coupled with each other, as well as their optimization processes. To this end, we proposed a co-optimization framework based on hierarchical Deep Reinforcement Learning (DRL), consisting of a configuration model and a motion model based on the Twin Delayed Deep Deterministic policy gradient algorithm (TD3). The two network models update asynchronously with a shared reward to ensure co-optimality. We conduct simulations and experiments with the Webots platform to validate the proposed framework, and the preliminary results show that it yields high quality optimization schemes and thus allows modular robots to be more adaptive to dynamic and multi-task scenarios.

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Section: Introductionmentioning

confidence: 99%

Co-optimization of Morphology and Behavior of Modular Robots via Hierarchical Deep Reinforcement Learning

Sun,

Yao,

Xiao

et al. 2023

Robotics: Science and Systems XIX

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“…Therefore, the field of Evolutionary Robotics has great motivation to study growth development. Nevertheless, not only is the field focused mostly on evolving the controller without evolving the body [13], but also has development received relatively little attention. Some developmental representations have become popular [14,15], but they have been mostly used for morphogenesis only.…”

Section: Introduction and Related Workmentioning

confidence: 99%

On the Schedule for Morphological Development of Evolved Modular Soft Robots

Nadizar

Medvet

Miras

2022

Lecture Notes in Computer Science

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Development is fundamental for living beings. As robots are often designed to mimic biological organisms, development is believed to be crucial for achieving successful results in robotic agents, as well. What is not clear, though, is the most appropriate scheduling for development. While in real life systems development happens mostly during the initial growth phase of organisms, it has not yet been investigated whether such assumption holds also for artificial creatures. In this paper, we employ a evolutionary approach to optimize the development-according to different representations-of Voxel-based Soft Robots (VSRs), a kind of modular robots. In our study, development consists in the addition of new voxels to the VSR, at fixed time instants, depending on the development schedule. We experiment with different schedules and show that, similarly to living organisms, artificial agents benefit from development occurring at early stages of life more than from development lasting for their entire life.

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“…Within engineering, the research areas related to artificial evolution are that of Evolutionary Computing Smith, 2003, 2015) and Evolutionary Robotics (Nolfi and Floreano, 2000;Doncieux et al, 2015;Nolfi et al, 2016). These fields have addressed the evolution of robot controllers (brains) with considerable success but evolving the morphologies (bodies) has received much less attention (Prabhu et al, 2018). Importantly, the influence of the environment has been even more scarcely investigated.…”

Section: Introductionmentioning

confidence: 99%

“…First, we allow changes not only to the brain but also to the body. While Evolutionary Robotics systems often focus on the evolution of the brain (Weigmann, 2012;Prabhu et al, 2018), we not only also permit the evolution of the body, but even its development. This is a fundamental refinement, given the known importance the body has for intelligence (Pfeifer and Bongard, 2006).…”

Section: Introductionmentioning

confidence: 99%

Environmental Regulation Using Plasticoding for the Evolution of Robots

2020

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Evolutionary robot systems are usually affected by the properties of the environment indirectly through selection. In this paper, we present and investigate a system where the environment also has a direct effect—through regulation. We propose a novel robot encoding method where a genotype encodes multiple possible phenotypes, and the incarnation of a robot depends on the environmental conditions taking place in a determined moment of its life. This means that the morphology, controller, and behavior of a robot can change according to the environment. Importantly, this process of development can happen at any moment of a robot's lifetime, according to its experienced environmental stimuli. We provide an empirical proof-of-concept, and the analysis of the experimental results shows that environmental regulation improves adaptation (task performance) while leading to different evolved morphologies, controllers, and behavior.

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A survey on evolutionary-aided design in robotics

Cited by 20 publications

References 102 publications

Co-optimization of Morphology and Behavior of Modular Robots via Hierarchical Deep Reinforcement Learning

Co-optimization of Morphology and Behavior of Modular Robots via Hierarchical Deep Reinforcement Learning

On the Schedule for Morphological Development of Evolved Modular Soft Robots

Environmental Regulation Using Plasticoding for the Evolution of Robots

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