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Autores principales: Depoortere, Joris, Driesen, Johan, Suykens, Johan, Kazmi, Hussain Syed
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2405.14472
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author Depoortere, Joris
Driesen, Johan
Suykens, Johan
Kazmi, Hussain Syed
author_facet Depoortere, Joris
Driesen, Johan
Suykens, Johan
Kazmi, Hussain Syed
contents Deep learning models have gained increasing prominence in recent years in the field of solar pho-tovoltaic (PV) forecasting. One drawback of these models is that they require a lot of high-quality data to perform well. This is often infeasible in practice, due to poor measurement infrastructure in legacy systems and the rapid build-up of new solar systems across the world. This paper proposes SolNet: a novel, general-purpose, multivariate solar power forecaster, which addresses these challenges by using a two-step forecasting pipeline which incorporates transfer learning from abundant synthetic data generated from PVGIS, before fine-tuning on observational data. Using actual production data from hundreds of sites in the Netherlands, Australia and Belgium, we show that SolNet improves forecasting performance over data-scarce settings as well as baseline models. We find transfer learning benefits to be the strongest when only limited observational data is available. At the same time we provide several guidelines and considerations for transfer learning practitioners, as our results show that weather data, seasonal patterns, amount of synthetic data and possible mis-specification in source location, can have a major impact on the results. The SolNet models created in this way are applicable for any land-based solar photovoltaic system across the planet where simulated and observed data can be combined to obtain improved forecasting capabilities.
format Preprint
id arxiv_https___arxiv_org_abs_2405_14472
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle SolNet: Open-source deep learning models for photovoltaic power forecasting across the globe
Depoortere, Joris
Driesen, Johan
Suykens, Johan
Kazmi, Hussain Syed
Signal Processing
Machine Learning
Deep learning models have gained increasing prominence in recent years in the field of solar pho-tovoltaic (PV) forecasting. One drawback of these models is that they require a lot of high-quality data to perform well. This is often infeasible in practice, due to poor measurement infrastructure in legacy systems and the rapid build-up of new solar systems across the world. This paper proposes SolNet: a novel, general-purpose, multivariate solar power forecaster, which addresses these challenges by using a two-step forecasting pipeline which incorporates transfer learning from abundant synthetic data generated from PVGIS, before fine-tuning on observational data. Using actual production data from hundreds of sites in the Netherlands, Australia and Belgium, we show that SolNet improves forecasting performance over data-scarce settings as well as baseline models. We find transfer learning benefits to be the strongest when only limited observational data is available. At the same time we provide several guidelines and considerations for transfer learning practitioners, as our results show that weather data, seasonal patterns, amount of synthetic data and possible mis-specification in source location, can have a major impact on the results. The SolNet models created in this way are applicable for any land-based solar photovoltaic system across the planet where simulated and observed data can be combined to obtain improved forecasting capabilities.
title SolNet: Open-source deep learning models for photovoltaic power forecasting across the globe
topic Signal Processing
Machine Learning
url https://arxiv.org/abs/2405.14472