基于人工神经网络的波能变换器无功控制

E. Anderlini , D.I.M. Forehand , E. Bannon , M. Abusara
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引用次数: 51

摘要

提出了一种波能变换器无功控制的无模型算法。利用人工神经网络将有效波高、波能周期、动力输出阻尼和刚度系数映射到平均吸收功率和最大位移。这些值是在跨越多个波周期的时间范围内计算的,数据在设备的整个生命周期内收集,以便每20个时间范围脱机训练网络。最初,控制器系数选择随机值,以实现充分的探索。然后,利用代价函数内的神经网络进行多起点优化。优化的目的是最大限度地吸收能量,同时限制位移以防止故障。利用升沉点减振器的数值模拟,分析了该算法在规则波和不规则波中的性能。一旦训练完成,该算法呈现出与最先进的无功控制相似的功率吸收。此外,不仅免除了点吸收器动力学模型消除了其相关的不准确性,而且还使控制器能够适应由老化引起的机器响应的变化。
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Reactive control of a wave energy converter using artificial neural networks

A model-free algorithm is developed for the reactive control of a wave energy converter. Artificial neural networks are used to map the significant wave height, wave energy period, and the power take-off damping and stiffness coefficients to the mean absorbed power and maximum displacement. These values are computed during a time horizon spanning multiple wave cycles, with data being collected throughout the lifetime of the device so as to train the networks off-line every 20 time horizons. Initially, random values are selected for the controller coefficients to achieve sufficient exploration. Afterwards, a Multistart optimization is employed, which uses the neural networks within the cost function. The aim of the optimization is to maximise energy absorption, whilst limiting the displacement to prevent failures. Numerical simulations of a heaving point absorber are used to analyse the behaviour of the algorithm in regular and irregular waves. Once training has occurred, the algorithm presents a similar power absorption to state-of-the-art reactive control. Furthermore, not only does dispensing with the model of the point-absorber dynamics remove its associated inaccuracies, but it also enables the controller to adapt to variations in the machine response caused by ageing.

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