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Abstract
As the share of global offshore wind energy in the electricity generation portfolio is rapidly increasing, the grid integration of large-scale offshore wind farms is becoming of interest. Due to the intermittency of wind, the stability of power systems is challenging. Therefore, accurate and fast offshore short-term wind speed forecasting tools play important role in maintaining reliability and safe operation of the power system. This paper proposes a novel hybrid offshore wind forecasting model based on swarm decomposition (SWD) and meta-extreme learning machine (Meta-ELM). This approach combines the advantages of SWD which has proven efficiency for non-stationary signals, with Meta-ELM which provides faster calculation with a lower computational burden. In order to enhance accuracy and stability, the signal is decomposed by implementing a swarm-prey hunting algorithm in SWD. To validate the model, a comparison against four conventional and state-of-the-art hybrid models is performed. The implemented models are tested on two real wind datasets. The results demonstrate that the proposed model outperforms the counterparts for all performance metrics considered. The proposed hybrid approach can also improve the performance of the Meta-ELM model as a well-known and robust method.
Highlights
Wind energy has been the leading renewable energy form to decarbonize energy production that helps reach the net zero targets across the world
This paper proposes a novel hybrid offshore wind forecasting model based on swarm decomposition (SWD) and meta-extreme learning machine (Meta-Extreme Learning Machine (ELM))
This study presents a new hybrid model based on SWD and Meta-ELM for short-term offshore wind speed forecasting
Summary
Wind energy has been the leading renewable energy form to decarbonize energy production that helps reach the net zero targets across the world. As of 2021, the global wind power capacity constitutes almost 50% of the global renewable power capacity excluding hydropower. The wind market set a yearly installed capacity record in 2020 with 93 GW, bringing global installed wind capacity to 743 GW [1]. Thanks to the cost reductions of larger turbines, innovations in installations and O&M, and reduced investor risk, the wind industry is set to continue growing [2]. With higher capacity factors and improvements in the full life cycle of processes, offshore wind is seen as a vital technology for the needed carbon mitigation and becoming competitive [3]. The levelised cost of electricity (LCOE) from offshore wind is expected to decline by 55% in 2030 [4]
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