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In Region III, where maintaining constant power output is crucial, the DPC outperforms both the baseline and MPC methods, reducing overshoot by 0.58 % and improving accuracy by 17.27 units compared to the baseline method. 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引用次数: 0
摘要
风能是一种重要的可再生资源,但有效利用风能需要先进的控制系统。本研究提出了一种以数据为中心的预测控制(DPC)系统,并通过金枪鱼群优化-反向传播神经网络(TSO-BPNN)对风力涡轮机的预测控制进行了增强。它就像一个智能工具,将深度学习、预测控制和强化学习创新性地融合在一起。与传统的控制方法不同,所提出的方法利用实时数据来优化风机性能,以应对波动的风力条件。该系统在 FAST 平台上进行了模拟验证,证明了它在两个关键运行区域的卓越性能。具体来说,在目标是最大限度地从风中提取电能的区域 II 中,与传统方法相比,DPC 的过冲减少了 1.07%,稳态误差提高了 36.14 个单位。响应时间与现有的模型预测控制 (MPC) 策略相当,确保了在不降低效率的情况下的实时适用性。在对保持恒定功率输出至关重要的区域 III 中,DPC 的性能优于基准方法和 MPC 方法,与基准方法相比,过冲减少了 0.58 %,精度提高了 17.27 个单位。这些结果凸显了所提出的 DPC 系统在多变风力条件下优化涡轮机性能的有效性,与传统方法相比,在精确度和控制精度方面都有显著提高。
Data-centric predictive control with tuna swarm optimization-backpropagation neural networks for enhanced wind turbine performance
Wind energy is a significant renewable resource, but its efficient harnessing requires advanced control systems. This study presents a Data-Centric Predictive Control (DPC) system, enhanced by a Tuna Swarm Optimization-Backpropagation Neural Network (TSO-BPNN) for predictive wind turbine control. It's like a smart tool that uses innovative fusion of deep learning, predictive Control, and reinforcement learning. Unlike traditional control methods, the proposed approach uses real-time data to optimize turbine performance in response to fluctuating wind conditions.
The system is validated using simulations on the FAST platform, which demonstrate its superior performance in two critical operational regions. Specifically, in Region II, where the objective is to maximize power extraction from the wind, the DPC achieves a 1.07 % reduction in overshoot and an improvement of 36.14 units in steady-state error compared to traditional methods. The response time remains comparable to existing Model Predictive Control (MPC) strategies, ensuring real-time applicability without sacrificing efficiency. In Region III, where maintaining constant power output is crucial, the DPC outperforms both the baseline and MPC methods, reducing overshoot by 0.58 % and improving accuracy by 17.27 units compared to the baseline method. These results highlight the effectiveness of the proposed DPC system in optimizing turbine performance under variable wind conditions, offering a significant improvement over traditional methods in both accuracy and control precision.
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Renewable Energy journal is dedicated to advancing knowledge and disseminating insights on various topics and technologies within renewable energy systems and components. Our mission is to support researchers, engineers, economists, manufacturers, NGOs, associations, and societies in staying updated on new developments in their respective fields and applying alternative energy solutions to current practices.
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