Estimating mixture hybrid Weibull distribution parameters for wind energy application using Bayesian approach

Agbassou Guenoupkati, A. A. Salami, Yao Bokovi, Piléki Xavier Koussetou, S. Ouedraogo
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Abstract

The Weibull distribution function is essential for planning and designing wind-farm implementation projects and wind-resource assessments. However, the Weibull distribution is limited for those areas with high frequencies of calm winds. One solution is to use the hybrid Weibull distribution. In fact, when the wind speed data present heterogeneous structures, it makes sense to group them into classes that describe the different wind regimes. However, the single use of the Weibull distribution presents fitting errors that should be minimized. In this context, mixture distributions represent an appropriate alternative for modelling wind-speed data. This approach was used to combine the distributions associated with different wind-speed classes by weighting the contribution of each of them. This study proposes an approach based on mixtures of Weibull distributions for modelling wind-speed data in the West Africa region. The study focused on mixture Weibull (WW-BAY) and mixture hybrid Weibull (WWH-BAY) distributions using Bayes' theorem to characterize the wind speed distribution over twelve years of recorded data at the Abuja, Accra, Cotonou, Lome, and Tambacounda sites in West Africa. The parameters of the models were computed using the expectation-maximization (E-M) algorithm. The parameters of the models were estimated using the expectation-maximization (E-M) algorithm. The initial values were provided by the Levenberg-Marquardt algorithm. The results obtained from the proposed models were compared with those from the classical Weibull distribution whose parameters are estimated by some numerical method such as the energy pattern factor, maximum likelihood, and the empirical Justus methods based on statistical criteria. It is found that the WWH-BAY model gives the best prediction of power density at the Cotonou and Lome sites, with relative percentage error values of 0.00351 and 0.01084. The energy pattern factor method presents the lowest errors at the Abuja site with a relative percentage error value of -0.54752, Accra with -0.55774, and WW-BAY performs well for the Tambacounda site with 0.19232. It is recommended that these models are useful for wind energy applications in the West African region.
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利用贝叶斯方法估计风能应用中的混合威布尔分布参数
威布尔分布函数对风电场实施项目的规划和设计以及风资源评价具有重要意义。然而,威布尔分布在无风高频率的地区是有限的。一种解决方案是使用混合威布尔分布。事实上,当风速数据呈现异质结构时,将它们分成描述不同风况的类别是有意义的。然而,单次使用威布尔分布会带来应该最小化的拟合误差。在这种情况下,混合分布为风速数据建模提供了一种合适的选择。这种方法被用来通过加权每个风速级别的贡献来组合与不同风速级别相关的分布。本研究提出了一种基于混合威布尔分布的方法来模拟西非地区的风速数据。该研究的重点是混合威布尔分布(WW-BAY)和混合混合威布尔分布(wh - bay),利用贝叶斯定理来表征西非阿布贾、阿克拉、科托努、洛美和坦巴库达站点12年的记录数据的风速分布。采用期望最大化(E-M)算法计算模型参数。采用期望最大化(E-M)算法对模型参数进行估计。初始值由Levenberg-Marquardt算法提供。并与经典威布尔分布的计算结果进行了比较。经典威布尔分布的参数估计方法包括能量模式因子、极大似然和基于统计准则的经验Justus方法。结果表明,WWH-BAY模型对Cotonou和Lome站点的功率密度预测效果最好,相对百分比误差值分别为0.00351和0.01084。能量模式因子法在阿布贾站点误差最小,相对百分比误差值为-0.54752,阿克拉为-0.55774,而WW-BAY法在Tambacounda站点的相对百分比误差值为0.19232。建议这些模型对西非地区的风能应用是有用的。
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来源期刊
CiteScore
4.50
自引率
16.00%
发文量
83
审稿时长
8 weeks
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