Evolved Control of Natural Plants

ACM Transactions on Autonomous and Adaptive Systems (TAAS) Pub Date : 2017-09-20 DOI:10.1145/3124643

D. Hofstadler, Mostafa Wahby, Mary Katherine Heinrich, Heiko Hamann, Payam Zahadat, P. Ayres, T. Schmickl

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引用次数: 8

Abstract

Mixing societies of natural and artificial systems can provide interesting and potentially fruitful research targets. Here we mix robotic setups and natural plants in order to steer the motion behavior of plants while growing. The robotic setup uses a camera to observe the plant and uses a pair of light sources to trigger phototropic response, steering the plant to user-defined targets. An evolutionary robotic approach is used to design a controller for the setup. Initially, preliminary experiments are performed with a simple predetermined controller and a growing bean plant. The plant behavior in response to the simple controller is captured by image processing, and a model of the plant tip dynamics is developed. The model is used in simulation to evolve a robot controller that steers the plant tip such that it follows a number of randomly generated target points. Finally, we test the simulation-evolved controller in the real setup controlling a natural bean plant. The results demonstrate a successful crossing of the reality gap in the setup. The success of the approach allows for future extensions to more complex tasks including control of the shape of plants and pattern formation in multiple plant setups.

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自然植物的进化控制

混合自然和人工系统的社会可以提供有趣的和潜在的富有成效的研究目标。在这里，我们将机器人装置和自然植物混合在一起，以指导植物在生长过程中的运动行为。机器人装置使用一个摄像头来观察植物，并使用一对光源来触发致光性反应，将植物导向用户定义的目标。采用进化机器人方法设计了该装置的控制器。首先，用一个简单的预定控制器和一株生长中的豆类植物进行初步实验。通过图像处理捕获了植物对简单控制器的响应行为，并建立了植物尖端动力学模型。该模型在仿真中用于进化机器人控制器，该控制器可以操纵植物尖端，使其遵循一些随机生成的目标点。最后，我们在实际装置中对仿真进化控制器进行了测试，以控制一株天然的豆类植物。结果表明，该装置成功地跨越了现实差距。该方法的成功允许未来扩展到更复杂的任务，包括在多个工厂设置中控制植物形状和图案形成。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ACM Transactions on Autonomous and Adaptive Systems (TAAS)

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