A Novel Denoising Technique and Deep Learning Based Hybrid Wind Speed Forecasting Model for Variable Terrain Conditions

Sourav Malakar, Saptarsi Goswami, Amlan Chakrabarti, Bhaswati Ganguli
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Abstract

Wind flow can be highly unpredictable and can suffer substantial fluctuations in speed and direction due to the shape and height of hills, mountains, and valleys, making accurate wind speed (WS) forecasting essential in complex terrain. This paper presents a novel and adaptive model for short-term forecasting of WS. The paper's key contributions are as follows: (a) The Partial Auto Correlation Function (PACF) is utilised to minimise the dimension of the set of Intrinsic Mode Functions (IMF), hence reducing training time; (b) The sample entropy (SampEn) was used to calculate the complexity of the reduced set of IMFs. The proposed technique is adaptive since a specific Deep Learning (DL) model-feature combination was chosen based on complexity; (c) A novel bidirectional feature-LSTM framework for complicated IMFs has been suggested, resulting in improved forecasting accuracy; (d) The proposed model shows superior forecasting performance compared to the persistence, hybrid, Ensemble empirical mode decomposition (EEMD), and Variational Mode Decomposition (VMD)-based deep learning models. It has achieved the lowest variance in terms of forecasting accuracy between simple and complex terrain conditions 0.70%. Dimension reduction of IMF's and complexity-based model-feature selection helps reduce the training time by 68.77% and improve forecasting quality by 58.58% on average.
基于去噪技术和深度学习的新型混合风速预报模型,适用于多变地形条件
由于丘陵、山脉和山谷的形状和高度不同,风流的速度和方向会有很大的波动,因此准确的风速(WS)预报对复杂地形至关重要。本文提出了一种用于短期风速预报的新型自适应模型。本文的主要贡献如下:(a) 利用部分自动相关函数(PACF)最小化本征模式函数(IMF)集的维度,从而减少训练时间;(b) 利用样本熵(SampEn)计算缩减后的本征模式函数集的复杂度。(c) 针对复杂的 IMFs 提出了一种新的双向特征-LSTM 框架,从而提高了预测精度;(d) 与基于持久性、混合、集合经验模式分解(EEMD)和变异模式分解(VMD)的深度学习模型相比,所提出的模型显示出更优越的预测性能。它在简单地形条件和复杂地形条件之间的预测准确率差异最小,仅为 0.70%。IMF 的降维和基于复杂性的模型特征选择有助于减少 68.77% 的训练时间,平均提高 58.58% 的预测质量。
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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